ࡱ>    b jbjb R mmtuG  , , , TN86767677=TN8RXDGGGGG"H HPPPPPPP,^RPaLP), HGGHHP<, , GG X<<<H, G, GP< t.Z  4J, , HP<< 3 , , ND $67!&>N"X0RXk?~a<aN<, N8N8)b$N8N8b 50 Hottest Companies in Bioenergy 2009-2010 Subscribers Selection Book Including company profiles and recommendations The 2009-10 50 Hottest Companies in Bioenergy TABLE OF CONTENTS Welcome Letter 3 Instructions for Selectors 4 Hot Fuels, Feedstocks and Processing Technologies (survey) 5 The 2008-09 50 Hottest Companies in Bioenergy 7 Candidate Profiles 2008-09 Top 50 companies (in order of rank) 8 Other Companies (in alphabetical order) 100 Some 2009-10 eligible companies not profiled 218 Biofuels Digest Recommendations Hot 50 Recommendations and Hotter than Hell lists 221 WELCOME! Dear Subscriber, First of all, thank you for participating in this years 50 Hottest Companies in Bioenergy. The information contained in this volume is not required reading. Rather, these company profiles, recommendations, and other materials, are here to assist you. You can use them, or not, as you see fit. The companies themselves supplied a lot of the material in this book I made an effort to edit out the promotional material and strike anything outrageous. If I missed something you think looks goofy, just skip by it. Hottest does not mean best, biggest or most significant it means the companies that are, in your judgment, the most worthy of attention. I hope you find the process enjoyable and educational! Sincerely yours, Jim Lane HOT FUELS, FEEDSTOCKS AND TECHNOLOGIES The following data is from an October 2009 Biofuels Digest reader survey.   THE 2008-09 50 HOTTEST COMPANIES IN BIOENERGY 1. Coskata 2. Sapphire Energy 3. Virent Energy Systems 4. POET 5. Range Fuels 6. Solazyme 7. Amyris Biotechnologies 8. Mascoma 9. DuPont Danisco 10. UOP 11. ZeaChem 12. Aquaflow Bionomic 13. Bluefire Ethanol 14. Novozymes 15. Qteros 16. Petrobras 17. Cobalt Biofuels 18. Iogen 19. Synthetic Genomics 20. Abengoa Energy 21. KL Energy 22. Ineos 23. GreenFuel 24. Vital Renewable Energy 25. LS9 26. Raven Biofuels 27. Gevo 28. St.1 Biofuels Oy 29. Primafuel 30. Taurus Energy 31. Ceres 32. Syngenta 33. Aurora Biofuels 34. Bionavitas 35. Algenol 36. Verenium 37. Simply Green 38. Carbon Green 39. SEKAB 40. Osage Bioenergy 41. Dynamotive 42. Sustainable Power 43. ETH Bioenergia 44. Choren 45. OriginOil 46. Propel Fuels 47. GEM Biofuels 48. Lake Erie Biofuels 49. Cavitation Technologies 50. Lotus/Jaguar Omnivore 2009-10 CANDIDATE COMPANY PROFILES 2008-09 HOT 50 #1 Coskata Based in: Illinois( Business: The company's process heats raw materials to 17800 degrees fahrenheit, then releases the material into a bioreactor where microbes convert the gas into ethanol, with a yield of 100 gallons per ton of feedstock at a cost of less than $1 per gallon. The company can co-locate with steel mills to convert CO into as much as 50 billion gallons of gasoline per year. Model: Technology licensor; owner and operator of a demonstration-scale facility. Past milestones: 1. Built a pilot-scale facility in Warrenville, Illinois. 2. Raised $19.5 million in a second round of funding that will be used towards construction costs of its first 100 Mgy cellulosic ethanol plant. General Motors and Khosla Ventures were among the investors in the first round of funding. Future milestones: 1. Building a 40,000 gallon demonstration plant for cellulosic ethanol in Madison, PA. The semi-scale plant in Pennsylvania will demonstrate the integrated operation of Coskata's gasification technology and what Coskata believes is the leading gallons per dry ton conversion rate for biomass. 1. Coskata projected in 2009 they it would reach 100 Mgy in annual production by 2012. 2. The company expects to build its first 50-60 Mgy commercial scale plant in the Southeast, with a focus on the US Sugar facility near Lake Okeechobee in South Florida. The company said that it's process reduces the use of water in refining by 50 percent compared to gasoline. Metrics: Coskata, which uses thermochemical and biological processes, says that it can produce 100 gallons of fuel per ton of waste. The Coskata model presupposes a yield of around 100 gallons per ton of biomass. Sugar cane grows at around 70.9 tonnes per hectare in India, and at 71 in Brazil; in Florida, yields are at 68 tonnes per hectare. 12 percent of that cane is sugar, which yields 1700 gallons of ethanol per acre, or more. The remaining 88 percent is bagasse for a Coskata process, or about 60 tonnes per hectare. To generate 100 million gallons in this model, Coskata will need 1 million tons, or 900,000 tonnes of biomass. That will require 15,00 hectares, or 32,500 acres. That's 51 square miles, or the area within 4 miles of a 100 million gallon refinery. A mighty plantation, but not long hauling distances. Coskata quotable quotes: "Speaking at the Advanced Biofuels Summit, Wes Bolsen, Coskata CMO said he was not worried in the short term about downstream development of ethanol distribution infrastructure, saying that in the context of building the first handful of 50-100 Mgy cellulosic ethanol plants that people were lining up to take the ethanol." "Coskata confirmed to Australian media that it plans to establish a 53 Mgy advanced biofuels plant in the state of Victoria, and was seeking a partnership that would help provide cellulosic ethanol, forest residues and building waste. The state government of Victoria also confirmed that it is in talks with Coskata, which is partly owned by General Motors, the parent company of Australia's largest auto maker, Holden." #2 Sapphire Energy Based in: San Diego, CA. Also has a 100-acre Pilot facility in Las Cruces, NM Year Founded: 2007 Annual Revenues: N/A Technology: Sapphire Energy is focused on the entire pond to pump value chain with over 230 patents or applications spanning the entire algae-to-fuel process. They are developing industrial algae strains through synthetic biology and breeding techniques and are building the technologies and systems for CO2 utilization, cultivation, harvesting and refining. The algae and processes developed are field tested at a New Mexico research and development center where all the processes -- from biology to cultivation to harvest and extraction -- can be performed at a pilot scale. These processes result in a product called Green Crude which can be refined into the fuels we use every day - gasoline, diesel and jet fuel. Fuel type: Green Crude can be refined into the three most important liquid fuels used by our society: gasoline, diesel and jet fuel. The fuels meet ASTM standards and are compatible with the existing petroleum infrastructure, from refinement through distribution and the retail supply chain. Major investors: Sapphire Energy is supported by a world-class syndicate of investors led by co-founder ARCH Venture Partners, along with the Wellcome Trust, Venrock and Cascade Investment, LLC. Past milestones (08-09): - First commercial airline test flights using algae-based, drop-in replacement fuel (Continental & JAL) - First vehicle to cross the US fueled by a blend of algae-based gasoline in an unmodified engine (Algaeus, in partnership with FUEL and The Veggie Van Organization) - Production timeline announced within 3 years Sapphire Energy expects to be nearing completion of a demonstration and test facility and well on its way to producing 1 million gallons of diesel and jet fuel per year over the next 5 years. By 2018, Sapphire expects to grow this to 100 million and by 2025 1 billion gallons of diesel and jet fuel per year. 3 major milestone goals (2010-11) - Begin construction on demonstration scale Integrated Algal Bio-Refinery (IABR) in New Mexico Business model: Develop technology and operate along the entire pond-to-pump value chain. Fuel cost: Sapphires planning goals are to be able to produce green crude at between $60 - $80 per barrel. Competitive edge: Sapphire Energys distinction as a company comes from its understanding of synthetic biology and its application to algae. Through this they have developed IP spanning the entire pond-to-pump value chain, representing over 230 patents and applications. Based on their strong IP position and freedom to operate these patents, Sapphire has caught the attention of a blue-ribbon syndicate of investors including ARCH Venture Partners, the Wellcome Trust, Venrock and Cascade Investment, LLC. Sapphire Energy is seen as a leader in the way they are approaching the problem. Sapphire is an energy company, using synthetic biology to make low carbon drop-in fuels. Sapphire is focused on manufacturing infrastructure compliant green crude that fits with the fuel transport and distribution systems we use today. They're focused on producing ASTM-certified fuels at a commercial scale without the use of sugar or any other feedstock. Sapphire's Green Crude is produced directly from CO2 and sunlight and the resulting fuel is not biodiesel, but high-value, renewable hydrocarbons. Alliances and Partnerships: Sapphire is collaborating with leading scientists from the Department of Energys Joint Genome Institute; University of California, San Diego; The Scripps Research Institute; Texas AM, NM State University, Scandia National Institute, University of Kentucky, University of Tulsa, and the San Diego Center for Algae Biotechnology. Development stage: Demonstration Website: www.sapphireenergy.com #3 Virent Based in: 3571 Anderson Street, Madison, WI 53704 (608) 663-0228 Year Founded: 2002 Annual Revenues: Confidential Technology: Virents patented catalytic BioForming process combines proprietary aqueous phase reforming (APR) technology with established petroleum refining techniques to generate the same range of hydrocarbon molecules now refined from petroleum. Fuel type: Green gasoline, diesel, jet fuel, and chemicals previously refined only from petroleum. Major investors: Cargill Ventures, Honda Strategic Ventures, Venture Investors LLC, and Advantage Capital. Past milestones (08-09): Announced collaboration with Royal Dutch Shell to develop biogasoline. Exceeded technical milestones and began scale-up of biogasoline production, including shipment of product for testing. Received prestigious government and industry recognition including the US EPAs Presidential Green Chemistry Challenge, the World Economic Forums Technology Pioneer, Red Herring 100 North America, and ICIS Innovation awards. 3 major milestone goals (2010-11) Design and construct commercial scale facility for the production of biogasoline. Complete additional strategic investments. Begin scale-up of diesel and jet fuel production. Business model: Owner/operator and licensing within strategic relationships Fuel cost: Preliminary analysis suggests that Virents BioForming process can compete economically with petroleum-based fuels and chemicals at current feedstock and crude oil prices ($60-70/bbl). Competitive edge: Virents BioForming technology provides numerous competitive advantages: Premium Liquid Fuel Products: The technology produces a wide range of high quality hydrocarbon fuels that have no barriers to full market adoption. With the same composition and energy content as petroleum fuels, these biofuels can be distributed through existing pipelines and fuel pumps, and used at high blends with, or as drop in replacements for, petroleum fuels in todays engines. They can also work in applications currently without viable biofuel solutions, such as air travel. Feedstock Flexibility: Sugar mixtures, including 5 and 6 carbon sugars, disaccharides, and other water soluble polysaccharides derived from sugar and energy crops, as well as agricultural and forestry waste, are possible feedstocks. This flexibility translates into more biomass options and lower input costs. Low Carbon Fuels: The process is CO2 neutral, water positive, and has low life cycle emissions. This energy efficient, exothermic process runs under moderate conditions and requires no external energy inputs. The process yields 30% more net energy than corn ethanol due to the natural separation of gasoline from water (ethanol distillation requires energy inputs of nearly 50% of its final energy content). Robust Catalytic Process: Catalysts provide increased productivity due to faster chemical reactions, proven process reliability, reduced energy requirements, and demonstrated scalability to large production volumes. In contrast to biological processes which depend on living enzymes or microbes, catalysts are capable of utilizing variable feedstocks and of producing a range of molecules. Cost-Competitive Biorefinery Solution: Feedstocks and end products can be optimized based on local market conditions. This fast and continuous (versus batch) process lowers capital expenditures, while low energy requirements reduce operating costs. Together, these attributes provide a biorefinery solution with a broad mix of high value products that are competitive with petroleum products at current prices. The BioForming process is a practical biorefinery alternative that can speed the use of non-food plant sugars as an energy source in place of petroleum, thus decreasing dependence on fossil hydrocarbons while minimizing the impact on global water and food supplies. Virents ability to produce hydrocarbon products that are both sustainable and economical is truly transformative. Alliances and Partnerships: Virent is collaborating with Royal Dutch Shell to develop and commercialize biogasoline. A tier one automobile company is supporting efforts to determine biogasolines suitability in current and next generation engines. Development stage: Pilot/Demonstration Virent is currently building the worlds first demonstration unit for the catalytic conversion of plant sugars to gasoline. The plant will have an annual capacity of 10,000 gallons. Website www.virent.com #4 POET Based in: South Dakota Business: Largest private first generation ethanol producer; developer of cellulosic ethanol technology (using corn cobs as a feedstock). Model: Owner-operator, holding minority stakes in most of its plants, with local investors. Past milestones: 1. Opening of the companys pilot cellulosic plant in Scotland, SD, producing cellulosic ethanol at a rate of approximately 20,000 gallons per year. 2. Completed its first corn cob collection season, and in a 16-day trial of new cob harvesting tecnology. 3. Announced the creation of POET Biomass, a division of POET devoted to managing harvest and transportation logistics for corn cobs POETs cellulosic feedstock as well as waste wood and other feedstocks to be used for cellulosic ethanol and alternative energy projects at their production facilities. 4. The POET Biorefining plant in Bingham Lake has deployed a new technology for eliminating water discharge, and the 35 Mgy corn ethanol plant is now using 2.64 gallons of water per gallon of ethanol produced, down from 3.42, with water discharges limited to steam and the water content in dried distillers grains and other byproducts. POET has been working on recycled water use, capturing 100 percent of its water used at its Portland, Indiana plant from recycled quarry water and 80 percent of its water at the Big Stone, SD plant from a power plant cooling pond. 5. With the city of Sioux Falls, completed a landfill gas pipeline that will supply methane gas to the 105 Mgy POET plant at Chancellor. The10-mile, low-pressure pipeline from the Sioux Falls Regional Sanitary Landfill will provide the landfill gas used a wood waste-fuel boiler to generate process steam. The two alternative energy sources will offset up to 90 percent of the plants process steam needs and could in the future replace 90 percent of the plants total energy needs. The partnership will provide revenues to Sioux Falls and reduce costs at the POET Chancellor plant. The project is the 460th around the country to utilize landfill methane. The pipeline cost the city $4.3 million, costs $300,000 to operate, and will generate $1.8 million in annual city revenue from sale of methane to POET. 6. POET received the 2008 Biofuels Digest Achievement Award for Cellulosic Ethanol. The award was given in recognition of achieving high yields and reduced energy inputs in ethanol production through its BPX technology. 7. Awarded the Energy Star designation for energy efficiency at its Ashton, IA plant. The 56 Mgy POET corn ethanol plant in Ashton, which opened in 2005, is equipped with combined heat and power (CHP) that generates up to 7.2 MW of electricity and requires 16 percent less fuel than a conventional process. The process saves 18,900 tons of CO2 emissions per year. Future milestones: 1. The company said that it expects to harvest up to 25,000 acres for cobs in Texas, South Dakota and Iowa in fall 2009. 2. 25 Mgy Project LIBERTY cellulosic ethanol plant in Emmetsburg, Iowa opens in 2011. Metrics: Can produce up to 3.0 gallons of ethanol per bushel of corn with its proprietary BPX technology. BPX also reduces energy needs for fermentation by 8 to 15 percent compared to other ethanol production processes. Targeting payments to farmers of $30 to $60 per ton for corn stover (cobs and stalk), and said that farmers could increase these payments through the Biomass Crop Assistance Program. An Iowa farm averages 1.5 tons of corn stover per acre, or $45-$90 per acre in value before BCAP payments are considered. #5 Range Fuels Based in: 11101 W. 120 Ave., Suite 200th , Broomfield, CO 80021 Year Founded: 2006 Annual Revenues: Range Fuels first commercial cellulosic biofuels plant, located near the town of Soperton, Georgia is scheduled to begin production in the second quarter of 2010. Specific financial information is proprietary. Technology: Range Fuels is focused on commercially producing low-carbon biofuels, including cellulosic ethanol, and clean renewable power using renewable and sustainable supplies of biomass that cannot be used for food. The company uses an innovative, two-step thermo-chemical process to convert non-food biomass, such as wood chips, switchgrass, corn stover, sugarcane bagasse and olive pits to clean renewable power and cellulosic biofuels. Range Fuels Two-step Thermo-chemical Conversion Process In the first step of the process heat, pressure and steam are used to convert the non-food biomass to a synthesis gas or syngas. Excess energy in this step is recovered and used to generate clean renewable power. In the second step the cleaned syngas is passed over a proprietary catalyst and transformed into cellulosic biofuels, which can then be separated and processed to yield a variety of low carbon biofuels, including cellulosic ethanol and methanol. These products can be used to displace gasoline or diesel transportation fuels, generate clean renewable energy or be used as low carbon chemical building blocks. Range Fuels is employing its proprietary two-step thermo-chemical conversion process in its first commercial cellulosic biofuels plant currently under construction and scheduled to begin production in the second quarter of 2010. Fuel type: Range Fuels thermo-chemical conversion process can generate a suite of low carbon biofuels from non-food biomass that can reduce the countrys dependence on foreign oil, create immediate jobs, and dramatically reduce GHG emissions. Major products potentially yielded include cellulosic ethanol, methanol, dimethyl ether, diesel fuel, green gasoline and clean renewable power. Potential customers for Range Fuels low carbon biofuels and clean renewable power include consumers, refined petroleum product suppliers, utilities and industrials, chemical companies, vehicle fleet operators and biodiesel producers. Major investors: Range Fuels and the Soperton Plant are supported by over $250 million in support from public and private sources, including a $76 million grant from the U.S. Department of Energy, an $80 million loan guarantee from the U.S. Department of Agriculture, and over $100 million from an oversubscribed Series B financing round completed in the spring 2008. The Company has also secured state and local incentives to support development of the Soperton Plant. Range Fuels was founded by Khosla Ventures LLC, a venture capital firm focused on the creation of renewable, environmentally-friendly energy sources. Range Fuels closed its Series B financing round, in which it raised over $100 million, in the spring of 2008. Investors in this round included Passport Capital, BlueMountain, Leaf Clean Energy Company (advised by EEA Fund Management Ltd. and Shaw Capital), Morgan Stanley, and PCG Clean Energy & Technology Fund (with participation by California Public Employees Retirement System). Range Fuels also received a $76 million grant from the U.S. Department of Energy, an $80 million loan guarantee through the U.S. Department of Agriculture and a grant of $6.25 million from the State of Georgia for the Soperton Plant project. Past milestones (08-09): In the spring of 2008 Range Fuels, Inc. closed its Series B financing round, raising over $100 million to help finance construction of its commercial cellulosic biofuels plant near the town of Soperton, Georgia. In November 2008 David C. Aldous joined the company as Chief Executive Officer, bringing 28 years of petrochemical experience to apply to the successful construction and operation of Range Fuels first commercial cellulosic biofuels plant. Immediately prior to joining Range Fuels, Aldous was Executive Vice President Strategy and Portfolio for Royal Dutch Shell in London, where he had responsibility for strategy, mergers, acquisitions, divestments, consulting, global systems, health, safety, security, environmental, and technology for Shells downstream business with revenues of more than $300 billion. In January 2009 the U.S. Department of Agriculture awarded Range Fuels a conditional commitment for an $80 million loan guarantee to assist construction of its commercial cellulosic biofuels plant near Soperton, Georgia. The loan guarantee falls under the Section 9003 Biorefinery Assistance Program authorized by the 2008 Farm Bill, which provides loan guarantees for commercial-scale biorefineries and grants for demonstration-scale biorefineries that produce advanced biofuels or any fuel that is not corn- based. The Biorefinery Assistance program is intended to assist in developing new and emerging technologies that produce advanced biofuels to increase the nations energy independence; promote resource conservation, public health, and the environment; diversify markets for agricultural products and waste material and spur rural economic development. In spring 2009 the Company intensified construction efforts on Phase 1 of the Soperton Plant, Reaching over 200 contractors and employees on site managing construction activities by the fall with major process systems delivered and installed at the site. 3 major milestone goals (2010-11) To begin production of cellulosic biofuels from Range Fuels Soperton Plant in the second quarter 2010 and be first to market with commercially produced cellulosic biofuels in the U.S. To advance build-out of the next phase of the Soperton Plant. Business model: Range Fuels will design, build, own and operate cellulosic biofuels plants in targeted development regions. Range Fuels goals are: To be first to market with commercially produced cellulosic biofuels by building on the Companys eight plus years of pilot plant operating experience and successful public and private financial support secured via an $80 million loan guarantee from the U.S. Department of Agriculture, an $100 million plus oversubscribed Series B round of private financing, a $76 million grant from the U.S. Department of Energy and a $6.25 million grant from the State of Georgia. To rapidly gain market share by capturing the best plant locations, i.e. those areas that have large, available supplies of low-cost renewable biomass that cannot be used for food, are sustainable and are near significant markets for low carbon biofuels and clean renewable power markets. To become the premier cellulosic biofuels producer by building a world-class project management team, with a focus on continuous process improvements to improve product yields and efficiencies, while simultaneously driving operating and capital costs down to become the low marginal cost supplier of cellulosic biofuels. Fuel cost: Range Fuels projects its operating costs will be competitive without financial support from the government. Specific cost information is proprietary. Competitive edge(s): (e.g. Distribution, economies of scale, low-cost, quality, location, vertically integrated model, location, yield, genetics). Range Fuels proprietary two-step thermo-chemical process can convert any type of non-food biomass into cellulosic biofuels. This feedstock flexibility reduces reliance upon specialized crops and any single geographic region as a feedstock source, which differentiates the process from traditional starch-based ethanol production and 2nd generation bio-chemical conversion processes, and promotes stable biomass supply and pricing. The process can produce a variety of low carbon biofuels that can be used to displace gasoline or diesel transportation fuels, generate clean renewable energy or be used as low carbon chemical building blocks. This ability to produce a variety of cellulosic biofuels, as well as produce clean renewable power in the process, reduces exposure to price volatility typically associated with specific commodity markets. Range Fuels technology has a zero carbon footprint and very low emissions. Our carbon life cycle analysis using standard models and including the positive impact of our generation of clean renewable power shows our Soperton Plant project, at full capacity, will have a negative carbon footprint or in other words we will have a greater than 100% reduction in greenhouse gases compared to fossil fuel-derived gasoline. This advantage relative to conventional starch-based ethanol production and traditional transportation fuels will become increasingly valuable as low carbon fuels standards and climate change legislation is implemented. Additionally, Range Fuels is the only company to have raised the necessary capital to begin construction on a commercial-scale cellulosic biofuels plant. Range Fuels has commenced construction on its first commercial cellulosic biofuels plant and plans to begin production from Phase 1 of the Soperton Plant in the second quarter 2010. Alliances and Partnerships: Range Fuels partners include: AMEC, providing non-process related engineering services, permitting-related services and construction management services for the Soperton Plant; CH2M Hill Companies, Ltd., providing additional permitting-related services for the Soperton Plant; Merrick & Company, assisting in process engineering design and design related services for Range Fuels biomass and catalytic syngas converters; Emerson Electric Co., supplying process control and automation systems plus system design and expertise; The Price Companies, Inc., providing feedstock procurement and wood chip handling services; TransMontaigne Product Services Inc., providing product marketing services; and Ceres, Inc., supporting use of dedicated energy crops to produce cellulosic biofuels. Development stage Range Fuels is currently constructing Phase I of its first commercial-scale cellulosic biofuels plant near Soperton, Georgia, which will employ Range Fuels innovative, two-step thermo-chemical conversion process. The plant will be the first in the U.S. to produce commercial quantities of low carbon biofuels from biomass, which includes all plant and plant-derived material, such as wood, grasses, and corn stover, and will also generate clean renewable power from energy recovered in the process of converting non-food biomass to cellulosic biofuels. Range Fuels Commercial Cellulosic Biofuels Plant, Soperton, Georgia The Soperton Plant will initially use wood from nearby timber operations and will transition to leftover wood residue over time. At full build-out capacity, the Soperton Plant is permitted to produce 100 million gallons of cellulosic biofuels each year and can use 2,625 dry tons of feedstock daily. The design of the Soperton Plant was informed by the operation of a fully integrated and automated pilot plant in Denver, Colorado, which successfully converted Georgia pine and hardwood as well as Colorado beetle-kill pine to cellulosic biofuels since the first quarter of 2008. Range Fuels Optimization Plant, Denver, Colorado The Denver-based Optimization Plant is a 4th generation pilot plant employing the two-step thermo-chemical conversion process being used by Range Fuels commercial cellulosic biofuels plant currently under construction near Soperton, Georgia. Over 10,000 hours of testing were performed on the four generations of pilot plants, which over an eight-year period processed over thirty different non-food biomass feedstocks, including wood waste, grasses, municipal solid waste and hog manure. Website: www.rangefuels.com #6 Solazyme Based in: California( Business: Solazyme, which was ranked #6 in the Hottest 50 Companies in Bioenergy for 2008-09 said that it will be developing markets in the high-end cosmaceutical and pharmaceutical sectors as well as continuing to make progress towards making biodiesel and jet fuel at commercially viable costs. The company utilizes a unique "grow in the dark" algae cultivation strategy, in which the algae is fed plant waste cellulosic and other cellulosic materials that contain sugars - the food is used in lieu of sunlight and CO2 to provide energy that algae convert into lipids. Model: Owner-operator Past milestones: 1. Closed a $57 million third round of funding. Funds were invested by Braemar Energy Ventures, Lightspeed Venture Partners, VantagePoint, Roda Group, Harris & Harris and Solazyme chairman Jerry Fiddler. 2. The California Energy Commission's Public Interest Energy Research program awarded a $789,697 Biosynthetic Transportation Fuel Production grant that will support the company's R&D efforts. The award takes nearly half of the $1.65 million program funding that PIER recently announced. 3. Selected by the U.S. Department of Defense to research, develop, and demonstrate commercial scale production of algae-derived F-76 Naval Distillate fuel for testing and fuel certification to demonstrate it meets all military specifications and functional requirements.The contract includes both R&D and fuel delivery components and calls for delivery of over 20,000 gallons of Soladiesel F-76 fuel to the Navy for compatibility testing over the next year. F-76 Naval Distillate is similar to diesel fuel and is the primary shipboard fuel used by the Navy. This program will lead to the eventual certification of Soladiesel F-76 Naval distillate for commercial sale to the U.S. Military. Future milestones: 1. CTO and co-founder Harrison Dillon said that the company would be at parity with $80 oil by 2012/13. 2. CEO Jonathan Wolfson said that he expected the company to be at 100 Mgy in production at that time. Metrics: Life Cycle Associates, the same consultant that performed lifecycle greenhouse gas calculations for the California Air Resources Board, completed a field-to-wheels assessment of Soladiesel, the company's algae-based biodiesel using the Argonne National Laboratories GREET model. LCA found that Soladiesel's full lifecycle greenhouse gas (GHG) emissions are 85 to 93 percent lower than standard petroleum based ultra-low sulfur diesel (ULSD). Additional testing by the National Renewable Energy Laboratory found that Soladiesel also generates a 30 percent reduction in particulates, a nearly 20 percent reduction in carbon monoxide and and a nearly 10 percent reduction in THC. Solazyme quotable quotes: "The company has now reached 60 employees and has raised $75 million in equity, expecting to commence sales into non-fuel markets for its omega-3 rich algae this year (2009)." "Solazyme received the Biofuels Digest Award for Achievement in Advanced Biofuels & Feedstocks. Solazyme received the award for their pioneering production of algae-based aviation fuel and motor transport biodiesel. #7 Amyris Biotechnologies Based in: 5885 Hollis Street, Emeryville CA Year Founded: 2003 Annual Revenues: ($60M, $14M, $6M) Technology: Synthetic Biology Fuel type: renewable diesel, jet as well as renewable chemicals Major investors: Kleiner Perkins, Khosla Ventures, TPG, Votorantim Top 3 milestones for 2008-09. 1. Scale up and Advancement of Commercialization: Opening of US pilot plant in Sept 08 to transition technology between Emeryville lab and Brazil where product production will occur. Simultaneously developed Brazil operations, including opening lab (aug 08), pilot plant (april 09), and demonstration facility (june 09). Engaged EPCM and have kicked off design work on first commercial facility. Have run processes in large, contract manufacturing facility with successful results. 2. Product Certification and Demonstration: Completed several road demonstrations of our fuel (including the Olympic Committee bus during April 2008 tour of Chicago) and received EPA certification of our renewable No Compromise diesel in 2009. 3. Financial Raised over $110M from the sale of equity from 2/08 to present to support scale up operations and initial commercial plant work. 3 major milestone goals (2010-11) Secure first commercial production site and begin construction for 2011 first commercial production. Secure off-take agreements with first customers for Amyris renewable products. Finalize agreements for expansion of production for 2012-2013. Business model: Focus on first production and scale up in Brazil using sugar cane as an economic, scalable, environmentally responsible feedstock (note- our engineered yeast strains can use a wide range of feedstock to produce our diesel) Fuel cost: Not disclosed Competitive edge: We intend to participate along the value chain by providing technology, leveraging others to produce our product, and to then market and distribute our proprietary products worldwide. In support of this model, we intend to grow our production in Brazil under a capital light model where producers invest the capital to convert their mills, then we market and distribute the produced products. We intend to distribute the product globally, working with strategic partners as appropriate on a geographic basis. We have already established US distribution capabilities through our subsidiary, Amyris Fuels, which is generating current revenue and establishing a US distribution network. Alliances and Partnerships: See previous answer re distribution. We are putting our first customer offtake agreements in place now in anticipation of 2011 commercialization. We have chosen to stay independent of any major partnerships to retain full commercial rights, but do intend to work with partners beginning 2010-2011 for production expansion, and for geographic, product specific offtake. Stage: Demo completed, advancing toward commercialization Website: HYPERLINK "http://www.anyris.com/"www.amyris.com and HYPERLINK "http://www.amyrisbrasil.com/"www.amyrisbrasil.com #8 Mascoma Based in: 67 Etna Road, Suite 300, Lebanon, NH 03766 Year Founded: 2005 Technology: Consolidated Bio-Processing (see below) Fuel type: Ethanol Major investors: HYPERLINK "http://www.flagshipventures.com/"Flagship Ventures, HYPERLINK "http://www.khoslaventures.com/"Khosla Ventures, HYPERLINK "http://www.atlasventure.com/"Atlas Venture, HYPERLINK "http://www.generalcatalyst.com/"General Catalyst Partners, HYPERLINK "http://www.kpcb.com/"Kleiner Perkins Caufield & Byers, HYPERLINK "http://www.pinnacleven.com/"VantagePoint Venture Partners, HYPERLINK "http://www.gm.com/"General Motors, HYPERLINK "http://www.marathonoil.com/"Marathon Oil Past milestones (08-09): First demonstration of CBP technology Opening of demonstration facility in Rome, NY Funding from the State of Michigan for commercial ethanol production facility 3 major milestone goals (2010-11) Breaking ground on Michigan commercial production facility Transfer of advanced CBP technology to our demonstration plant in Rome NY Completing next round of funding Business model: Owner / Partner Fuel cost: Mascoma Corporation is actively involved in research. Not producing ethanol commercially. According to models, the final cost of fuel continues to decrease. Competitive edge: The unique technology developed by Mascoma Corporation uses yeast and bacteria that are engineered to produce large quantities of the enzymes necessary to break down the cellulose and ferment the resulting sugars into ethanol. Combining these two steps (enzymatic digestion and fermentation) significantly reduces costs by eliminating the need for enzyme produced in a separate refinery. This process, called Consolidated Bioprocessing or CBP, will ultimately enable the conversion of the solar energy contained in plants to ethanol in just a few days. Alliances and Partnerships: GM, Chevron, Marathon Oil, US DOE, State of NY, State of Michigan Development stage: Demonstration Website: HYPERLINK "http://www.mascoma.com/"www.mascoma.com #9 DuPont Danisco Based in: 500 Park Blvd, Suite 545 ( Itasca, IL 60143 Year Founded: Joint Venture formed May 2008 Annual revenues: Pre-revenue Type of technology: Fermentation Fuel type: Cellulosic ethanol Major investors. Formed by DuPont and Danisco 3 top milestones for 2008-09. Formation of JV Site and funding of demonstration facility Start up of Vonore, TN demonstration facility by end of 2009 (250,000 gallons operated on cobs and switchgrass) 3 major milestone goals for 2010-11. Site 25MGY cob plant Site 15MGY switchgrass plant Develop and sell beta licenses for early deployment Business model: Licensing Fuel cost: Competitive with gas at commercial scale plants (at BTU level) Competitive edge: * soil to tank knowledge and plan * competitive, robust technology * solid funding from parent companies with reach back capabilities into both parents for R&D, legal, finance etc Alliances and Partnerships: * $140M funding from parents * 90 scientists from DuPont and Danisco dedicated to project * Partnership with State of TN building Demonstration facility in Vonore, TN (State put in $40M) * Partnership with Genera Energy, LLC in TN to supply switchgrass to demonstration plant * Sun Grant with Iowa state on cob collection for conversion to ethanol Development stage: Demo Website: HYPERLINK "http://www.ddce.com/"http://www.ddce.com/ #10 UOP Based in: Illinois( Business: Honeywell s UOP has developed a renewable jet fuel processing technology, as well as a joint venture. UOP and Ensyn announced the formation of a new joint venture, dubbed Envergent Technologies, that will market technologies and equipment for generating power, transportation fuel and heating oil from biomass using pyrolysis. The joint venture will utilize forest and agriculture residues as feedstocks in a Rapid Thermal process, where feedstocks are heated in the absence of oxygen, to produce pyrolysis oils that can be utilized directly in heating oil or power gen. UOP also owns a Renewable Energy & Chemicals business that produced green diesel using its Ecofining process. UOP and Vaperma announced a partnership to bring Vaperma's polymer membrane technology to the ethanol industry, where it will reduce energy consumption and emissions for for first-generation ethanol, as well as cellulosic ethanol and butanol. Model: Licensor; often develops technologies in partnerships. Past milestones: In 2006-09, Virgin Atlantic, Continental, Japan Air Lines and Air New Zealand and the group as a whole conducted a series of laboratory, ground and flight tests, indicating that test fuels performed as well as or better than typical petroleum-based Jet A. The tests revealed that using the Bio-SPK fuel blends had no adverse effects on the engines or their components. They also showed that the fuels have an average 1.8 percent greater energy content by mass than typical petroleum-derived jet fuel. In 2009, at the Paris Air Show Boeing and a series of partners involved in four biofuels-based test flights released the data from the tests, and said that with the release they are on a path towards flight certification of biofuels as soon as late 2010.( ( Future milestones: UOP expects to commence licensing its fuel technology in 2009, and said that it has already commenced advanced discussions with multiple potential licensees. The consistent message from airlines and aircraft manufacturers is that the certification of biofuels for regular commercial flights is in the 2012/13 timeline. Boeing spokesman Terrance Scott said that biofuels could be a regular source for jet fuel with 3-5 years, with algae becoming a common component in 8-10 years.( ( Metrics: UOP said that it was modeling future refineries for renewable jet fuel using a 60-150 Mgy scale, and said that while this was only a fraction of the typical 4.2 billion gallon per year scale of a typical oil refinery that the size was the most effective given the expected supply chain for renewable jet fuel feedstocks. UOP said that it expects the cost of refineries to be in the $150 million range. UOP quotable quotes: "Although biofuels have been successfully tested at 50 percent blends, industry guidance is pointing to a 30 percent blend. The consistent view is that drop-in fuels that do not require changes in infrastructure will be the norm." The Hot 50 for 2009-10 will be released Tuesday, 12/1. Between now and then, you'll see profiles of potential candidates in the Digest, and you'll have a chance to vote for your favorites. Reader response will count for 50 percent of a company's overall score in the preparation of the rankings. The remaining 50 percent is voted by a panel of experts. #11 ZeaChem Based in: 165 S. Union Blvd, Suite 380, Lakewood, CO 80228 Year Founded: 2002 Annual Revenues: 2007: 0; 2008: 0; 2009: minimal Technology: ZeaChems technology is a parallel hybrid system of fermentation and gasification. This hybrid process achieves 40% higher yield than other cellulosic processes. ZeaChems patented biorefining process uses an acetogen a species of bacteria naturally adapted to digest the tough carbon chains of cellulose to extract the maximum amount of energy available from the feedstock. ZeaChem offers the highest yield, lowest production cost and lowest carbon emissions profile of any known biorefining process. Fuel type:. A unique differentiator of ZeaChems technology is the ability to produce a range of cellulosic bio-based products to serve a variety of market sectors. While corn ethanol and many cellulosic technologies are captive to single or limited markets, ZeaChems entirely new approach can produce many chemicals and fuels within various carbon chain product groups. Production facilities will be capable of producing the products that will yield the best margin. Should market conditions change, a ZeaChem facility will have the option of changing the products produced which provides flexibility that is simply not available to a biorefinery that is captive to a single market. ZeaChem is developing an entire portfolio of third generation fuels and intermediate chemicals derived from cellulosic biomass, including several value-added chemicals purchased by chemical companies to create popular commercial and industrial products. See chart below for complete product portfolio: ZeaChem Carbon Chain Product GroupsC2 ChainC3 ChainC4 ChainC6 ChainAcetic Acid Ethyl Acetate Ethanol Ethylene Ethylene GlycolLactic Acid Propylene Glycol Acrylic Acid & Esters Propionic Acid Propylene Methacrylic Acid & EstersButanolHexanol Hexene Major investors: ZeaChem raised a Series A round in 2006 for $6MM from Mohr Davidow Ventures (MDV) and Firelake Capital. A Series B was raised in 2008 for $34MM led by PrairieGold Venture Partners and Globespan Capital Partners with follow on investment from MDV and Firelake Capital. Valero Energy Corporation, the nations largest petroleum refiner, also invested during the Series B. Past milestones (08-09): COMPLETE: In 2008, a successful Series B of $34MM was achieved to fund ZeaChems demonstration scale biorefinery (see above and HYPERLINK "http://zeachem.com/press/pressrelease010809.php"press release for details). COMPLETE: ZeaChem is working with CH2MHILL as the Engineering, Procurement and Construction (HYPERLINK "http://zeachem.com/press/pressrelease022309.php"EPC) contractor on the engineering design package for the demonstration scale biorefinery. By the end of 2009, ZeaChem will begin construction of its demo facility, proposed to be built in Boardman, Oregon. ON-TARGET: ZeaChem continues to develop strategic partnerships and anticipates one or more announcements of partnerships by the end of 2009 in the fuels and/or chemicals industries. In addition, ZeaChem projects one or more announcements of successful local, state and/or federal financing to accelerate ZeaChems deployment strategy. 3 major milestone goals (2010-11) ZeaChem will successfully construct, start-up, and operate the demonstration scale biorefinery and bring first product(s) to market. ZeaChem will begin engineering design for its first commercial-scale biorefinery. ZeaChem will initiate research and development of the three carbon (C3) product platform. Business model: ZeaChems first objective is to build, own and operate facilities in strategic markets. ZeaChem maintains the option of awarding direct licenses to qualified parties where it makes sense. The complexities of building plants internationally will also present opportunities to license the technology. Fuel cost: ZeaChems advantage in operating costs puts its process at a competitive advantage to both corn based ethanol producers and cellulosic ethanol competitors. Given its 40% yield advantage, ZeaChems process has the lowest operating (<$1.00) and capital cost (<$4.00) per gallon. These costs include feedstock cost of $60/BDT as included in the National Renewable Energy Laboratorys most recent technology update. Competitive edge: ZeaChems strategy is to control input costs so that it can remain the lowest cost producer. Choose feedstock that can be cultivated and delivered locally. Have patented a highly efficient and flexible process to convert that feedstock into not just one niche product but a portfolio of high-value chemicals and fuels. Role is to develop and demonstrate the technology, partnering with large chemical and petroleum companies to offer them a reliable, low-cost, sustainable solution. Distribution: A goal for ZeaChem production facilities is to have strategic off-take agreements within established distribution channels that have access to the markets that can be served by the facility. A unique differentiator of ZeaChems technology is the ability to produce a range of products to serve a variety of market sectors. ZeaChem will form strategic partnerships with fuels and chemicals companies to bring cellulosic bio-based products to market. Economies of scale: ZeaChems high-yield process gives it sustainable competitive advantage in both economics and environmental impact. ZeaChems advantage in operating costs puts its process at a competitive advantage. Quality: The market for bio-based chemicals and fuels are each in the trillions of dollars, leaving plenty of room for innovation. A number of cellulosic companies have unveiled various biorefining approaches, but none of these processes can match ZeaChems yield and cost advantages. Several companies have announced plans to build pilot and demo plants, but none have begun full-scale commercial production. Location: A key strategy for ZeaChem is to co-locate its biorefineries with dedicated energy crops. Such co-location offers synergies and savings in harvesting and transportation of renewable biomass to the biorefinery. In addition, ZeaChem will produce bio-based products which make the most economic sense in terms of the product markets available and strategic partnerships. Yield: ZeaChems hybrid technology combining the best of biochemical fermentation and thermochemical gasification delivers the highest yield per ton of biomass in the industry. Theoretical maximum for biochemical and thermochemical players is approximately 100 gallons/BDT compared to ZeaChems theoretical maximum of 165 gallons/BDT. At 85% efficiency, actual yield for biochemical and thermochemical only processes will be around 90 gallons/BDT compared to 135 gallon/BDT for ZeaChems technology. This significant yield advantage translates into economic saving and environmental benefits. Land productivity and yield is also important to ZeaChem. Assuming a yield of 15 BDT/acre, a dedicated energy crop biomass farm with an approximate 5 mile radius could support a ZeaChem biorefinery with capacity of 100 million gallons per year (MM GPY). This translates into net land productivity rates nearly five times higher than existing approaches. Genetics: ZeaChem uses a naturally occurring bacteria, an acetogen, in its fermentation process. There is no genetic modification to the bacteria. Also, the hybrid poplar trees grown by feedstock partner GreenWood Resources, are not genetically modified, but are developed using traditional breeding methods where desirable traits are selected but not modified. Alliances and Partnerships: Bringing in key strategic partners to provide both industry knowledge and set up potential monetization opportunities for either the business or particular product/geographic segments is an important focus area for ZeaChem. This is true for all stages of deployment: research and development, demonstration, and commercialization. ZeaChem has a number of potential business segments that will necessarily involve strategic partners. Specific markets include ethanol, other fuels, and chemicals. Development stage ZeaChem will be breaking ground on its demonstration scale biorefinery in 2009 with first product online in 2010. The biorefinery will be based on the C2 product platform which includes ethyl acetate, ethylene and ethanol. Website URL. www.zeachem.com #12 Aquaflow Bionomic Based in: New Zealand( Business: Aquaflow has developed technology to harvest wild algae from municipal sewage ponds, farm outflows or rivers. Aquaflow's manufactures 40-feet containers which can be deployed in remote locations, and scaled. The company's approach avoids upfront capital costs of other algae-based fuel technologies based on development of monocultures, ponds or bioreactors. Model: Sale of equipment and remediated water sales. Interestingly, the company's investor projections do not include revenue from the sale of green crude or carbon credits. However, the company has said that it can charge royalties, and produce revenue from the algae feedstock, green crude and other products that result from its process. Past milestones: 1. The company has been running a pilot plant at the Blenheim District Sewage ponds in and has produced 40 tonnes of algae to date. As early as March '08 the company said that it had achieved commercial-scale algae harvest levels at its plant in Marlborough, and said that its new bioreactor installations were expected to bring the company to commercial-scale production of biocrude within the next few months. 2. By September 08, Aquaflow said it had produced its first batch of commercially competitive green crude oil made from algae oil. The crude oil product is made from wild algae grown on human sewage. Company executives said that the development was significant because the company could separate fuels such as diesel fuels, aviation fuels, and high-value chemicals, from a green crude product. 3. In October 2008, Aquaflow signed a partnership with Honeywell UOP to provide algal oil for conversion to drop-in jet fuel. 4. In July '09, Aquaflow and Solray Energy announced a partnership that will join Aquaflows technology for harvesting algae grown in wastewater to Solrays algae to fuel conversion process. Solray, in turn, is a joint venture between solvent recovery firm Solvent Rescue and heating equipment manufacturer Rayners. At present, Solray converts about one-third of the algal biomass to bio-crude, but is researching improvements to its process. 5. Pure Power invested $3 million for a 19.9 percent stake in the company. Future milestones: 1. Aquaflow Bionomics announced in August '09 that it has commenced a $2.09 million capital raise in Australia, the last private raise before an IPO expected in the next 12 months. It's IPO will float 60 million shares and is expected to raise $20-$30 million. The company said it will use the funds to invest in R&D for its continuous flow algae production technology, which focuses on water remediation as well as fuel production. The company operates a prototype algae production facility in Blenheim, and has successfully tested harvest of wild algae. 2. Aquaflow said it is in discussions with 16 projects on three continents, including with municipal authorities and the private sector. Metrics: Aquaflow's investor presentation includes forecast revenue of $4.4 million in 2010/11, rising to A$94.4m in 2014/15. Nick Gerritson (Director) quotable quotes: "It's plug and play, we just plug into the existing infrastructure." #13 BlueFire Ethanol Company name: BlueFire Ethanol Fuels (OTC BB:BFRE.OB) Based in: 31 Musick, Irvine, CA 92618 Year Founded: 2006 Annual Revenues: - 2009- 5 million Technology BlueFire Ethanols own commercially ready, patented, and proven Concentrated Acid Hydrolysis Technology Process for the profitable conversion of cellulosic ("Green Waste") waste materialsto ethanol, a viable alternative to gasoline. Fuel type: Ethanol Major Investors Quercus Trust owns approximately 20% of the company 8. 3 top milestones for 2008-2009 1. Received permits for Lancaster facility. 2. Teamed up with Solazyme 3. Deploying $40 MM award from U.S. Department of Energy to complete Mississippi facility 3 major milestone goals (2010-11) 1. Construct and begin operation of Lancaster facility 2. Finance and construct Fulton, MS facility 3. Company to become profitable Business model: Owner/operator. Fuel cost: For the 1st facility, the fuel production cost will be approximately $1.60 a gallon. Fuel cost will be sub $1 a gallon on larger facilities. Competitive edge: BlueFire will locate its facilities near the end markets for the ethanol which gives it a competitive advantage over traditional ethanol production. BlueFire will also be able to produce at a lower cost by being located next to or in existing landfills, eliminating transportation cost. #14 Novozymes Annual revenues 2009 (projected), 2008, 2007: 2009 (projected after Q2 results): slightly positive growth in local currencies >3% 2008: 8.14 million DKK (1.6 billion USD) 2007: 7.4 million DKK (1.45 billion USD) Type of technology: Novozymes second generation cellulosic technology is a biochemical conversion using enzyme hydrolysis. Novozymes production of bioethanol from corn and other cereals is based on a biochemical conversion of starch into fermentable sugars. Enzymes are processing aids applied in different parts of the process, mainly liquefaction and saccharification. 3 top milestones for 2008-09: Novozymes launched the Cellic product family, which have the best cost performance of any cellulosic ethanol enzymes commercially available, and are our first commercial enzymes for cellulosic bioethanol. Novozymes launched Spirizyme Ultra and Spirizyme HS for saccharification. These top-performing enzymes provide yield increases for starch bioethanol production. Novozymes launched Liquozyme SC 4X for liquefaction. This top-performing enzyme provides yield increases for starch bioethanol production. In early 2009, Novozymes broke ground on a new USD 200 million production facility in Blair, Nebraska, to meet demand for enzymes for the production of first and second generation bioethanol. 3 major milestone goals for 2010-11: Novozymes will launch new enzyme products for both starch and cellulosic bioethanol production. Novozymes will launch our next cellulosic bioethanol enzymes in 2010. Novozymes will help the industry obtain significant reduction in production cost with our cellulosic enzymes. Competitive edge: Novozymes is the leader in enzyme technology with the best-performing enzymes in the industry for both starch and cellulosic bioethanol. Distribution, research, marketing or production partnerships or alliances: Novozymes is the market leader in all segments and partners with many of the industry leaders, such as COFCO, Sinopec, and POET. Metrics: ~14% of revenues reinvested in R&D Commitment to providing commercially viable cellulosic enzymes by 2010 Business: Novozymes is the world leader in bioinnovation. Together with customers across a broad array of industrieswe create tomorrows industrial biosolutions, improving our customers' business, and the use of our planet's resources. With over 700 products used in 130 countries, Novozymes bioinnovations improve industrial performance and safeguard the worlds resources by offering superior and sustainable solutions for tomorrows ever-changing marketplace. Novozymes offers the leading technology platform for biofuel production; we are the leading enzyme provider for ethanol enzymes in all regions where we operate. Model: Novozymes supplies enzymes to the bioethanol production industry and has more than 60% market share. Past milestones: In 2009, Novozymes launched three new products: the Cellic product family for cellulosic bioethanol, which has the best cost performance of any cellulosic ethanol enzymes commercially available, and are our first commercial enzymes for cellulosic bioethanol; Spirizyme HS, a high-strength formula for starch bioethanol which combines all of the benefits of the Spirizyme brand with lower costs; and Liquozyme SC 4X for starch bioethanol, which combines all of the benefits of the best liquefaction brand on the market with lower costs. In early 2009, Novozymes broke ground on a new USD 200 million production facility in Blair, Nebraska, to meet demand for enzymes for the production of first and second generation bioethanol. In 2008, Novozymes launched the product Spirizyme Ultra for starch bioethanol, our premium saccharification enzyme, a highly-effective glucoamylasethatgivesplants the potential for higher ethanol levels and shorter fermentation times. Future milestones: Novozymes will launch new enzyme products for both starch and cellulosic ethanol production, including our next cellulosic ethanol enzymes in 2010, which can provide a significant reduction in production cost performance. Metrics: In 2008, Novozymes revenues were USD 1.6 million; of this, approximately 14% was reinvested in R&D. We have more than 150 people in R&D dedicated to biofuel R&D working on various feedstocks and technologies for cellulosic bioethanol. Novozymes is the leader in enzyme technology with the best-performing enzymes in the industry for both starch and cellulosic bioethanol. Novozymes is the only enzyme provider to commit to providing commercially viable cellulosic enzymes by 2010, when we anticipate production costs for cellulosic bioethanol will become comparable with first generation #15 Qteros Based in: Massachusetts Business: Developer of a "one-step" process for conversion of cellulosic biomass to ethanol. The company's signature IP is the "Q Microbe", a species of clostridium, which is a naturally-discovered (but subsequently enhanced) consolidated bioprocessor that consumes (pre-treated) biomass, converts to simple sugars and then converts into ethanol. Model: Licensing. The company is constructing a pilot plant as a demonstration of its technology, but plans to license on a royalty basis thereafter. Capacity of the pilot is currently secret, but is in the "thousands of liters". Past milestones: 1. Strain development. 2. Achieving a 70 gram per liter - 7 percent concentrations of ethanol by weight (9 percent by volume) - naturally, clostridia tend to achieve 2-3 percent concentrations, causing distillation costs to soar - while other leading cellulosic ethanol developers have as yet reached 5 percent. 3. Raising $25 million+ from Valero, BP, Venrock, Battery Ventures and Soros Fund Management. Future milestones: 1. Look for its pilot plant to open in 2010 in Solutia, MA. The company is "well aligned" with the emerging timelines for cellulosic ethanol producers that would be candidate licensees of the Qteros system. 2. Look for expansion to Brazil - bagasse is a natural for cellulosic ethanol production - they are already collected in the cane harvest process - as opposed to agricultural residues that have to be collected. 3. Transfer work to other feedstocks - utilization based on geography. Metrics: Q Microbe saves 30 percent on the cost of cellulosic conversion compared to 5 percent concentration. The process realizes 100 gallons of ethanol per ton of corn stalks, Qteros quotable quotes: "What we're really making is cheap sugars. Once you have that you have compounds that are identical to precursors for many useful products. " - Kevin Gray, CTO Qteros will not need fossil fuel inputs for fertilizer or distillation of the ethanol because the lignin portion of the plant material (about 1/3 of most plants) will be burned to generate the heat necessary to refine the ethanol. There will also be leftover green electricity created. - Jef Sharpe, EVP #16 Petrobras Based in: Brazil Business: Oil and gas producer with sugarcane ethanol and biodiesel operations. Model: State-owned operator. Announced that it was not seeking to acquire distressed ethanol companies but would establish partnerships where appropriate to support development of the national ethanol industry. According to Petrobras management, the state oil giant would offer a guaranteed ethanol contract over 10 years in return for a minority stake in a project. Local developers would hold the majority interest. Past milestones: Gabrielli said that "We are not only expanding our position in the ethanol market within Brazil. We want to be a big player in the international ethanol market. Right now we have a joint venture in Japan with a Japanese company that involves developing a business model to increase the ethanol market there. We own 87 percent of a refinery in Okinawa and we already sell gasoline blended with ethanol in Japan. We plan to use our facilities in Japan to be an important hub in the ethanol business of that nation." Petrobras Biocombustvel CEO Miguel Rossetto said that the Brazilian state oil giant has targeted $2 billion in biodiesel and ethanol investment through 2013, and aims to achieve a 15 percent share of the Brazilian ethanol market and up to 25 percent market share in biodiesel. Petrobras and Camargo Correa have combined their pipeline building efforts into a single entity, PMCC, that will link Uberaba in Minas Gerais to the sugarcane processing center of Paulinha in Sao Paulo state, and then to ports and export terminal in Sao Sebastiao and Ilha d'Agua. The pipeline is expected to commence operation in 2010, will be fully completed in 2012, and will transport up to 3.17 billion gallons of ethanol per year. The project cost is expected to reach $1.5 billion and will transport up to 40 percent of ethanol production from Brazil's southern region. Future milestones: Petrobras Biocombustvel has previously announced plans to invest $475 million in the biofuels sector in 2009, and become a top 5 global biofuel producer by 2020 with a total investment program of $2.8 billion between 2009 and 2013. Has entered into talks of partnership and/or investment with Brenco, the Brazilian ethanol producer that counts AOL founder Steve Case, Vinod Khosla and Bill and Hillary Clinton among its direct and indirect investors. Brenco said that it may sell a controlling stake to Petrobras, or merge with ETH Bioenergia, the ethanol company founded and controlled by Odebrecht. Metrics: Petrobras, which has set a goal of 500 Mgy in ethanol exports by 2013, said it will invest $2.5 billion in ethanol development through 2013, with another $800 million dedicated to biodiesel. Set a company $174.4 billion five-year business plan based on a baseline projection of $65+ oil. #17 Cobalt Biofuels Based in: 500 Clyde Ave, Mountain View, CA 94043( ( Year Founded: 2006( ( Annual Revenues: $0( ( Technology: Integrated biorefinery and biomass electricity generation. Biofuels production involves fermentation of non-food cellulosic (hemicellulose and cellulose) feedstock. Lignin is passed to the onsite boiler and generates sufficient power to serve the needs of the biorefinery, with significant excess power exported to the grid. Fuel type: Butanol, electricity and a small amount of acetone.( ( Major investors: Vantage Point Venture Partners, Pinnacle Ventures, Malaysian Life Sciences Capital Fund, Life Sciences Partners, @Ventures, Burrill & Company, Harris & Harris( ( Past milestones (08-09): 1. Raise Series C equity (done) 2. Demonstrate pretreatment of woody biomass and fermentation of C5 sugars in stable, continuous fermentation at bench scale (done) 3. Build and operate a pilot facility (done)( ( 3 major milestone goals (2010-11) 1. Build scale up facility 2. Raise Series D equity 3. Procure site, complete design and obtain financing for commercial scale facility Business model: To be determined on a project-by-project basis. Intend to be owner/operator, with outside equity participation, in Initial commercial facility. On an ongoing basis, expect to be both owner/operator and licensor, on a project-by-project basis. ( ( Fuel cost: Fuel cost per gallon: $1.02 per gallon, cost calculated as cost of production, minus revenue from co-products, and assuming feedstock (woody biomass) cost of $38.50 dry metric tonne (per DOE EERE 2009 goal) and natural gas cost of $7.50 1000 scf. Co-products priced according to their BTU content per guidance from the DOE ($0.025 per 1000 BTUs). Competitive edge: Low capital costs compared to other cellulosic biofuels companies, patent-pending, high productivity bioreactor design, high margins generated by use of low cost feedstock, plant design and engineering for energy efficiency, significant co-product revenue (electricity) Alliances and Partnerships: In formation.( ( Development stage Pilot( ( Website: HYPERLINK "http://www.cobaltbiofuels.com/"www.cobaltbiofuels.com ( #18 Iogen Based in: Canada Business: Cellulosic ethanol production Model: Owner-operator. Past milestones: In 2009, a Shell station in Ottawa became the first in the country to serve cars with cellulosic ethanol, offering a 10 percent blend of gasoline and wheat straw ethanol manufactured at a demonstration-scale cellulosic ethanol plan jointly owned by Shell and Iogen. A representative of the joint venture said that a decision on expansion would be reached within 12 months, and did not rule out the possibility of constructing a commercial-scale facility in Idaho, where the company abandoned an effort to build a demonstration-scale plant. Last October, Iogen announced that it had commenced shipments of a 47,000 gallon cellulosic ethanol order from venture partner Royal Dutch Shell. The companies first partnered in cellulosic ethanol in 2002 when Shell invested in Iogen. Shell subsequently increased its ownership stake in Iogen's technology to 50 percent in 2007. Under an expanded agreement with Shell, Codexis will optimize the efficiency of Iogen Energy'scellulosic ethanol catalysts, as well as developing new to convert biomass directly into green gasoline or green diesel. Future milestones: The Saskatchewan provincial government signed an agreement with Iogen to support development the province's first cellulosic ethanol plant at a former pulp mill at Prince Albert owned by Domtar. Iogen will operate the plant, which will be a commercial-scale expansion of its wheat straw ethanol demonstration plant in Ontario. The Canadian government has pledged up to 40 percent of the cost of the project in the form of development grants. The plant will also feature power generation from forest residues. In 2008, the Canadian federal government approved a $500 million cellulosic ethanol project plan by Iogen Corp for construction in Saskatchewan. Iogen execs said that they hoped to launch the 23 Mgy plant north of Saskatoon by 2011, using wheat straw and other cellulose as feedstock. Iogen is backed in the venture by Shell, Goldman Sachs and Petro Canada. Metrics: The Iogen technology has been operating at a 480,000 gallon per year capacity since 2004, and is currently evaluating options to construct an 18 Mgy plant in Saskatchewan, near Prince Albert. #19 Synthetic Genomics Based in: California Business: Synthetic biology and algal fuel developer. Model: R&D partner Past milestones: ExxonMobil, the last of the oil majors to commit to a major investment in biofuels, announced that its Research and Engineering unit will invest $300 million into in-house algae research, and up to an additional $300 million in La Jolla-based Synthetic Genomics, the genetics firm founded by J. Craig Venter that has been working on algae-to-energy research since 2005. SGI has developed techniques for harvesting algal oils, and will focus research on increasing lipid content by manipulating algal strains. The ExxonMobil investment in SGI is contingent on the meeting of R&D goals, according to a report in the New York Times. "This agreement between SGI and EMRE represents a comprehensive, long-term research and development exploration," said Venter. "We are confident that the combination of our respective expertise in science, research, engineering and scale-up should unlock the power of algae as biological energy producers in methods and scale not previously explored." "After considerable study, we have determined that the potential advantages and benefits of biofuel from algae could be significant," said Emil Jacobs, EMRE's VP of R&D. The venture is presented as a research collaboration rather than a commercialization effort at his stage, and could be classified to some extent opposite a $500 million investment made in 2007 by BP in the Energy Bioscience Institute. Chevron has also previously partnered with Solazyme and the National Renewable Energy Laboratory on research efforts in the algae-to-energy field. But for sheer magnitude of investment, the focus on a single bioenergy feedstock, and the focus on a single R&D partner in Synthetic Genomics, the announcement is without parallel in biofuels history. It may not be possible to interpret this investment as, in itself, a new and imminent path towards algal fuel commercialization, but it can be regarded as confirmation that ExxonMobil, after a famously long delay, has entered the renewable energy arena, and is placing its bet on algae. What does this bode for other high-profile algae-to-energy companies? "We think it's good for algae, and good for us," said Tim Zenk, VP of Corporate Affairs for Sapphire Energy. "The research collaboration announced today sends a loud and clear message that drop-in-replacement liquid transportation fuel produced from algae, above all other biologic choices, is the most viable option to replace crude oil. Algae fuels have significant environmental benefits over crude oil with lower carbon emissions, and are scalable to help nations transition to a secure energy future." Algae 2020 author Will Thurmond was similarly bullish. "Exxon-Mobils $600 million dollar commitment to algae based bio-crude and biofuels," Thurmond said, "represents another affirmative commitment by major petroleum companies, research laboratories, private investors and governments that are looking beyond the research and development phase, and are now entering the next stage to scale up and build out industrial-scale systems based on innovative, emerging and disruptive technologies." Future milestones: In California, a report on Craig Venter in Discover focuses on the Syntehtic Genomics founder's ambitions to develop synthetic life forms. While researchers have succeeded in "stitching together pieces of synthesized DNA" and transplanting that to a host bacterium; but the bacterium has been rejecting the genome as an invader, until recent efforts to add methyl tags to M. mycoides allowed the genome to go unnoticed by the bacterial defense system. The prize? Energy microbes that become monocellular biorefineries, consuming waste energy and converting it to biofuels. It is unclear whether the Synthetic Genomics research effort with ExxonMobil in algae will directly benefit from the R&D effort, as algae is a much more highly complex organism than bacteria. But Venter told the Times, "Assuming we dont make any errors, I think it should work and we should have the first synthetic species by the end of the year." Metrics: $300 million commitment to SGI is reportedly on a milestone-based, stage-gate basis. #20 Abengoa Energy Abengoa Bioenergy Addresses: St. Louis Year Founded: USA - 1982 EU - 1998 Brazil - 2007 Annual revenues 2009 (projected), 2008, 2007: (Parent Company) Abengoa is a technological company that applies innovative solutions for sustainable development in the infrastructure, environment and energysectors. Revenues and Gross Cash Flows in 2008 of 3,114.5 and 545.3 million euros, respectively. Operations in over 70 countries. Abengoas strategic development is based on generating forward-lookingoptions needed for a sustainable world. Type of technology(s): a. Traditional fermentation of cereal grains and sugar cane for the commercial production of bioethanol b. Traditional transesterification for the production of biodiesel from cereal and vegetable oils. c. Multiple technology options for the commercial demonstration of cellulosic fuel production. Fuel Type: Bioethanol, biodiesel. Major investors. Parent Company is public (ABG) on the Madrid (SIBE) exchange. Major milestones for 2008-09. New Facility start-ups o Biodiesel (San Roque, Spain) o France ethanol plant (55 MMGPY) o Indiana and Illinois grass-roots ethanol facilities (88 MMGPY each) o Biomass commercial demonstration facility at BCyL, Spain Commenced construction: o Two 70-MW Cogen facilities at both Brazil facilities o 110 MMGPY ethanol facility in Rotterdam Instituted GHG Inventory system to support Sustainability goal. EU Parliament approved Renewable Energy and Fuel Quality Directives. o Direct Blending of ethanol in Spain (beginning in 2010) Major milestone goals for 2010-11. Commence construction: o DOE Biomass commercial demonstration facility (15 MMGPY) o Ethanol facility in UK o Ethanol facility in Germany Complete construction and start-up of three 75-MW Cogen facilities in US Certify products as Sustainable using GHG reduction data, Certificates of Origin Business model: Owner / Operator Fuel cost: Depends on feedstock cost and energy cost. Competitive edge(s): Distribution (own marketing company), economies of scale provides low-cost, quality (only Fuel Ethanol company that is registered to ISO-9001), locations (three continents), R&D investments. Distribution, research, marketing or production partnerships or alliances. Industrial Partners NatureWorks (formerly Cargill Dow) Novus International Monsanto Genencor O2Diesel Universities Auburn University Kansas State University University of Concepcin University of Buenos Aires Lund University University of Sevilla University of Nebraska Research Centers Asociacin de Investigacin y Cooperacin Industrial de Andaluca - AICIA Centro de Investigaciones Energeticas, Medioambientales y Tecnologicas - CIEMAT National Renewable Energy Laboratory - NREL Pacific Northwest National Laboratory - PNL Argonne National Laboratory - ANL Instituto Catalysis y Petroquimicos - ICP Instituto Tecnologico de Aragon - ITA Centro de Investigacion y Desarrollo en Automocion - CIDAUT Washington University - St. Louis UOP Stage Commercial, pilot and demonstration. Website URL. www.abengoabioenergy.com #21 KL Energy Based in: 306 East Saint Joseph Street Suite 200, Rapid City, SD 57701 Year Founded: 2003 Annual Revenues: N/A Technology Type: Thermal Mechanical Fuel type: Cellulosic ethanol, lignin (including use as a high energy lignin pellet) Major investors: Various strategic non-institutional investors. Past milestones (08-09): Moving beyond our pilot plant to the opening in 2008 of the first USA based 2nd generation commercial scale demonstration plant producing cellulosic ethanol and high energy lignin and protein based co-products from forestry waste. Development of a commercially viable, shovel-ready technology, based on an environmentally friendly thermal -mechanical pretreatment and enzymatic hydrolysis process that works with various non-food feedstocks, including several types of woody biomass and bagasse. KL Energy has achieved or exceeded established industry benchmarks. Becoming a listed company and obtaining substantial investor funding over the last 14 months in an extremely difficult market, providing sufficient capital for development of technology into a commercially viable business model. Future Milestones: a) Commissioning and start-up of at least 5 currently identified cellulosic based energy projects with 100,000 to 200,000 metric ton processing capacity, over 3 continents by the middle of 2012. b) Identifying and beginning construction on a minimum of 5 additional 100,000 to 200,000 metric ton cellulosic based energy projects by the end of 2013. c) Formalizing national and international strategic partnerships and alliances that accelerate the commercialization of KLE technology, while proving and retaining a competitive edge in the industry. Business model: Owner-operator and licensor-partner. Fuel cost: Between $1.25 and $1.50 per gallon, before any federal or local incentives. Competitive edge: a. KLEs technology is commercially viable today before the positive effects of federal and local incentives. b. KLEs commercially viable technology is capacity flexible, providing scalable, custom designed CBE plants tailored to the feedstock availability and the local market. Locating CBEs near feedstock significantly reduces transportation costs. c. KLEs technology preserves the value of the co-products, resulting in optimum economic usage of the feedstock. d. The co-products from the KLE technology, primarily lignin, have various valuable uses due to its high Btu content, including as a high energy lignin pellet. e. KLEs technology does not include gasification or substantive amounts of acid, resulting in lower capital costs, lower operating costs, and minimum fermentation toxicity, low water usage, resulting in an environmentally friendly process. f. KLEs technology results in high slurry concentrations, well above NREL heat material balance assumptions, resulting in substantially lower capital costs and operating costs. g. KLEs technology, while feedstock flexible, is very effective on various woody biomass and bagasse, feedstock available in plentiful supply in key markets throughout the world. The effective management of forests requires the management of woody biomass. h. KLEs alliances with investor partners provide valuable opportunities for future growth. i. KLEs experience with designing and operating highly efficient first generation ethanol plants provides significant competitive advantages for the implementation of KLEs commercially viable technology. j. As a result of lower capital costs, lower operating costs, and the valuable co-products, KLE is able to profitably scale down capacity levels substantially below competitors to serve specific local markets for feedstock and off-put products. k. KLEs investor partners, including those in the energy industry, are not a limiting factor in the direction and scope of the companys future operations and opportunities. Alliances and Partnerships: KLE is in the process of formalizing several strategic alliances and partnerships. KLEs investor partners experience and relationships in the energy industry have opened several opportunities for CBE projects, research and development, and distribution of ethanol and co-products, both nationally and internationally. Convinced by the results of KLEs commercial scale demonstration plant, several 2nd generation enzyme and yeast producers partner with KLE for their testing on a commercial scale. Development stage KL Energy Corporations technology is commercially viable today, even before the substantial government incentives available. Metrics: The commissioning and start-up of 10 profitable CBE plants by 2013. Website: HYPERLINK "http://www.klenergycorp.com"www.klenergycorp.com . Quotable- From the beginning, we have focused on developing clean technology based on the economics of ethanol and high energy lignin by-products, including lignin pellets, from non-food feedstock. This focus has allowed us to become the first technology and commercially viable 2nd generation bio-fuel company that is ready to build profitable CBEs today. With our international investor partners and licensing agreements, we are able to rapidly implement our profitable business model throughout the world. #22 INEOS Bio Based in: 3030 Warrenville Rd., Suite 650, Lisle, IL 60532 Year Founded: August 1984. The company was renamed INEOS Bio after the acquisition by the INEOS Group of Bioengineering Resources Inc. (BRI) in July 2008. Annual Revenues: < $1m Technology type: The INEOS Bio process is a combined thermochemical and biochemical technology for ethanol and power production. It is comprised of four main steps: (1) feedstock gasification, (2) synthesis gas fermentation (3) ethanol recovery and (4) power generation. The process utilizes a patented fermentation process, where cleaned, cooled synthesis gas is converted selectively into ethanol by a naturally occurring anaerobic bacteria. The process has been under development for 18 years. Fuel type: Bio-ethanol & Renewable Power Major investors: INEOS, the third largest chemical company in the world, is the sole owner of the company and technology. Past milestones (08-09): 1. Complete the basic engineering and design package for the first demonstration of the technology in a commercial-scale unit. 2. Continue testing of additional sustainable feedstocks in the pilot plant. The feedstocks successfully tested include: wood waste, MSW, sugar cane bagasse, corn stover, and auto shredder residue. 3. Continued successful pilot plant testing to support the engineering design. The pilot plant has been in operation for 6 years (2003-2009). The unit is now generating emissions data in support of permitting of the first commercial- scale unit. 3 major milestone goals (2010-11) 1. Issue the EPC bid package for the first 8myg/yr commercial-scale unit. Begin construction in 1Q 2010. 2. Execute additional licenses with licensees in the Americas and Europe. 3. Commission and startup the first commercial unit in 3Q 2011. Business model: INEOS Bio will be an owner/operator of the first commercial-scale plant via a joint venture with New Planet Energy. INEOS Technologies (also part of the INEOS Group) is the leading licensor of chemical process technology in the world. INEOS Bio will adopt a similar business model to Technologies and it expects to monetize the technology through owner projects, joint ventures and licensing of the technology. This approach will leverage the skills, experience and resources of INEOS and its Technologies business. Fuel cost: With a zero or negative cost feedstock, we forecast the ability to produce for $1.00 per gallon (or less). Competitive edge: INEOS Bio is uniquely positioned to commercialize this next generation technology. We have an experienced team of engineers, scientists, IP Legal, business development, logistics, and marketing professionals who have developed and commercialized new chemical process technologies and who have designed, built, commissioned and operated world-scale facilities. The technology has been successfully demonstrated at lab scale for 18 years and at large (1.5 te/day) pilot scale for six years utilizing a wide range of feedstocks. No other technology in this space has this type of track record. The technology has a competitive advantage versus other biofuels technologies through its feedstock flexibility and ability to covert a number of different carbonaceous materials into both biofuels and renewable power. The INEOS Bio technology can be located near both the feedstock and distribution centers, thus providing an advantage for logistics intake as well as fuel off take and generation of renewable power. The use of zero or negative cost feedstocks provide an advantage in producing a lower cost and competitive biofuel. The plant has the ability to switch feedstocks based on their availability and relative cost to ensure that we are always using the most economically and environmentally sustainable feedstock at all times. Alliances and Partnerships: INEOS Bio is part of the INEOS Group of companies. INEOS is one of the largest independent refiners and producers of biofuels in Europe. Development stage Demonstration at Commercial Scale. 6 years of successful pilot plant testing at large scale (1.5 tons/day) with varied feedstocks has been completed. Engineering and permitting now to demonstrate the technology in a commercial- scale facility (8mgy/yr) with startup expected 3Q 2011. Website: www.ineosbio.com #23 Vital Renewable Energy Based in: Brazil Business: Ethanol producer and infrastructure owner/developer. Model: Owner-operator Past milestones: In 2008, Vital Renewable Energy announced a fund of $1 billion that will be used to launch ethanol and power projects. Leaf Clean Energy Company, Petercam Asset Management and PCG Clean Energy & Technology Fund are among participants in the fund, which is led by Paladin Capital Group. Vision Brazil Investments advised the funds investing in this round of financing. The company has commenced its first plant in Sao Paulo state, in partnership with Grupo Farias, which has 10.5 million tons of sugarcane processing capacity throughout Brazil. Future milestones: VREC plans to invest in a broad range of new projects in Brazil related to ethanol and energy generation. They also will consider purchases of existing ethanol facilities and investment opportunities in ethanol infrastructure. VREC aim is to benefit from the extensive operational expertise of its local partners and to leverage on its ability to identify strategic opportunities, promptly capturing an important share of its market. www.vrec.com #24 GreenFuel Technologies (company closed) #25 LS9 Based in: 100 Kimball Way, San Francisco CA 94080 Year Founded: 2005 Annual Revenues: 2009: n/a 2008: n/a 2007: n/a Technology: A microbial, fermentation based process that enables the cost effective conversion of renewable plant biomass into advanced biofuels that are drop-in compatible with the existing infrastructure. The same technology platform enables the production of a diversity of high-value chemicals. Fuel type: UltraClean"! Diesel, other UltraClean"! Fuels, and high-value chemicals Major investors: Flagship Ventures, Khosla Ventures, Lightspeed Venture Partners, and Chevron Technology Ventures 3 top milestones for 2008-09: 1) Entered into a strategic partnership with Procter & Gamble to support the joint development and commercialization of LS9 technology to produce key chemicals used within the P&G portfolio of consumer chemicals 2) Secured significant equity investment from Chevron Technology Ventures 3) Announced test results confirming that LS9s UltraClean"! Diesel meets or exceeds ASTM standards for use on U.S roads and ANP specifications for use on Brazilian roads 9. 3 major milestone goals for 2010-11: 1) Demonstration scale production of renewable transportation fuels 2) Another strategic partnership agreement 3) Significant scale-up of high-value chemicals production Business model: 1) Technology development 2) Production (owner/operator) Fuel cost: At full scale commercial production levels, LS9 estimates fuel production costs will be approximately $1.50 per gallon Competitive edge: LS9 is the only 1-step process for the production of drop-in compatible advanced biofuels LS9s process affects a high carbon footprint reduction when compared to conventional petroleum based-production processes in most cases yielding reductions of 85% LS9s 1-step technology, compared to competitors multi-step processing technology, is highly cost competitive LS9s proprietary 1-step process offers 90% energetic yield LS9s technology platform supports cost effective production of both clean transportation fuels and renewable chemicals LS9s technology is feedstock agnostic thereby, making it well positioned to quickly incorporate cellulosic-based feedstocks when those technologies come on-line 13. Distribution, research, marketing or production partnerships or alliances: 1) Strategic partnership with Procter and Gamble supporting the joint development and commercialization of LS9 technology in the production of high-value chemicals used in the production of consumer products. 2) Research and development collaborative with Lawrence Berkeley National Lab Joint BioEnergy Institute at University of California Berkeley. 14. Development stage:: 1) Pilot plant operating since August 2008 2) Rapidly scaling-up with demonstration scale production anticipated in 2010 15. Website URL: www.ls9.com #26 Raven Biofuels Based in: 61 South Paramus Rd; Paramus, NJ 07652-1236 Year Founded: 2007 Annual Revenues: Pre revenue Technology: Two stage dilute acid hydrolysis Fuel type: Ethanol, Furfural and high value organic specialty chemicals Major investors: Tribune Capital Partners, I2BF 3 top milestones for 2008-09: 1. Technology: Advancement of technology with multiple process improvements, Complete Process Review by Leading, Global Engineering Firm, Technology Development to Commercial Stage. 2. Projects: Two sites under development in Mississippi and British Columbia 3. Joint Venture: Established Joint Venture in British Columbia 3 major milestone goals (2010-11) Break Ground on First and Second Commercial (11MGY) Integrated Biorefinery, Complete Construction and Commence Operations of First Biorefinery. Business model: Owner/Operator. Fuel cost: This cost for ethanol and chemicals produced cannot easily be separated. It is the biorefinery model (total output of all products) especially furfural that makes the economics of Ravens business attractive. Competitive edge: True Biorefinery model- Multiple products of ethanol and furfural with high value furfural and other products adding increased profitability and market diversification, low cost production, commercially ready technology, location/feedstock availability, and vertically integrated model Alliances and Partnerships: Kamloops Indian Band for fibre supply in BC, Larson Engineering (U.S.), Sandwell Engineering (Canada), Price Biostock (U.S.) for feedstock sourcing. Development stage Commercially ready Website: www.ravenbiofuels.com #27 Gevo Based in:345 Inverness Dr. South; Bldg. C; Suite 345, Englewood, CO 80112 Year Founded: 2005 Annual Revenues:. N/A Technology: Fermentation of all sugars including mixed sugars from cellulosics to biobutanol. Fuel type: Gevo will produce biobutanol that can be blended directly into gasoline (at any ratio without the need to modify standard engines) and be used to make renewable hydrocarbons (green gasoline), diesel, and jet fuel, chemical intermediates and biobased plastics. Major investors: Khosla Ventures, Burrill & Company, Malaysian Life Science Fund, & Total SA Past milestones (08-09): Successfully complete production of biobutanol at 1 MGPY demo plant in St. Joe. MO. Launch Gevo Development for the acquisition of production assets. 3 major milestone goals (2010-11) Acquire first commercial scale facility(ies). Business model: Gevo will develop its technology for retrofitting of ethanol plants to produce biobutanol and own & operate capacity via its development company. Gevo Development has an flexible business model, i.e., it will raise capital to acquire assets either through direct acquisition, joint venture or tolling arrangements. Gevo, Inc. will also license its technology. Fuel cost: N/A Competitive edge: Gevos proprietary technology is a cost efficient ($0.30/gallon) and rapid (6-9 months) retrofit of first generation ethanol capacity to make biobutanol. Gevos exclusive collaboration with ICM, the premier engineering services company in the ethanol industry with over 60% of the installed capacity, is another competitive advantage. Finally, the ability to help finance and develop projects via Gevo Development, LLC provides a platform for full deployment. Gevo will be able to deploy cellulosic butanol technology as soon as conversion technology is available for biomass refineries. Alliances and Partnerships: Gevo has an exclusive collaboration with ICM for the retrofit of ethanol plants in North America. There are research collaborations with UCLA, Cal Tech and Catholic University, Leuven, Belgium Development stage Demo - commercial Website: www. Gevo.com #28 St. 1 Biofuels Oy Based in: Purotie 1, 00380 Helsinki, Finland Year Founded: 2006 Annual Revenues: 2009: 10 m (projected) 2008: 4,9m 2007: 0,01m Technology: Continuous fermentation Fuel type: Ethanol Major investors: Subsidiary of Finnish privately owned energy company St1 Oy Past milestones (08-09): Building and opening four new plants utilizing different food industry waste and sidestreams. Feedstock is from local bakeries, potato processing plant, sweet manufacturing and brewery. Also old dated bread waste form markets are utilized after mechanical package removal. Opening of Dehydration plant in Hamina Finland in June 2008. Dehydration plant completes the dispersed ethanol production concept. Launching of RE85, the first domestic high blend ethanol biofuel in Finland in April 2009 Development of Bionolix plant type. BionolixTM plant uses household biowaste and commercial biowaste as feedstock. 3 major milestone goals (2010-11) Building and Opening of the first BionolixTM plant in Hmeenlinna, Finland. Developing and building second generation cellulosic ethanol pilot plant. Business model: Own ethanol production in home markets: Finland, Sweden, Poland and Norway. Licensing technology, partnerships in other countries. Fuel cost: Production cost $1,90 / gal Competitive edge: Waste feedstock, Dispersed production, Energy efficiency While producing sustainable bioethanol, Etanolix technology also provides a sustainable waste management system and reduces the total amount of waste. Local fuel production increases countrys energy independence and decreases the need for imported fossil fuels. This combined to better utilization of waste makes the Etanolix technology unique in terms of CO2 balance and ecology. The concept has positive impact also on employment through production plants and Refuel RE85 distribution. Waste to Ethanol is a considerable tool when trying to reach EUs waste and biofuel directives. The concept is easily adaptable to countries around the world. Waste that is used as feedstock in the technology is available everywhere as is the need for successful waste management solutions. This combined to the global need for renewable energy ensures the potential in the market for this product. Alliances and Partnerships: St1 Oy has 650 petrol stations in Finland, Sweden, Norway and Poland. This station network can be used for distribution and marketing. Technology research partner has been VTT, The Finnish Research Centre of Finland. Development stage Commercial Website: HYPERLINK "http://www.st1.eu/"www.st1.eu #29 Primafuel Based in: California Business: Primafuel is active in globally strategic markets in the US, Europe and Asia. As part of its drive toward zero-carbon fuels, Primafuel's infrastructure projects have earned accolades and awards from leading authorities such as the California Air Resources Board. The company owns patent-pending technologies that improve the biofuels production process including waste-stream recycling, scalable and modular refineries, carbon-tracking infrastructure and the use of next-generation feedstocks. Model: Service provider. Past milestones: In 2008, Primafuel received a World Economic Forum "Technology Pioneer Award" for innovation in biofuels production and distribution infrastructure. Primafuel announced last spring the creation of a new biofuels technology solutions subsidiary, Primafuel Solutions. The team s initial offering is SMAART"!Oil, a down-stream system that extracts more food and fuel from the same bushel of corn. "Many advanced biofuels technologies have applications right now, with first-generation biofuels," said Rahul Iyer, co-founder of the company. "For example, we have a proprietary pretreatment technology that improves the efficiency of the corn oil extraction process, and an extensive portfolio of IP that will allow us to target more food-grade and fuel-grade materials, as well as other higher value compounds," he said. "The days of having just two products, ethanol and DDGs, are over." The Primafuel systems are tailored to each clients facility, and corn oil extraction rates will vary from facility to facility. Primafuel evaluates a range of samples (free of charge) from the clients plant, and extraction rates and performance guarantees are based on these tests Like companies such asGreenShift, the basic corn oil extraction technology involves a centrifuge process to separate the oils from the corn silage. Companies are differentiating themselves by packaging finance and post-production marketing services for ethanol clients in a tough balance sheet environment; Primafuel's focus on using advanced technology to customize a range of high-value compounds gives it a further point of differentiation. Future milestones: In 2009, Primafuel announced that it would enter the algae production sector with a licensing agreement with Ben-Gurion University Microalgae Biotechnology Lab in Israel. The company's biorefinery technology team had previously been recognized as a Technology Pioneer by the World Economic Forum for transformational biomass processing technologies. Primafuel execs said that the company would combine upstream algae production and downstream biorefinery systems. #30 Taurus Energy Based in: SE 22370 LUND SWEDEN Founded: Feb 2007 Revenues: Pre-revenue Technology type: Fermentation of pentoses for ethanol production Fuel type: Ethanol Previous milestones: Agreement with the Technical University of Lund , the Technical University Chalmers and SEKAB to run a project supported by the Swedish state Energimyndigheten The project has the title Industrial verification of fermentation of pentoses MoU with an Indian company and also a NDA with an ethanol producer To have 3 licensing agreements in place with major ethanol producers Future milestones: To offer our fermentation technology of pentoses for ethanol production to potential ethanol producers both old and new Our technology can be used in both existing ethanol plants and new plants Our patent portfolio consists of 13 patents of which 12 are direct tied to fermentation technology of pentoses One patent is a production patent to be used in an SSF process (Simultaneous Saccharification and Fermentation) resulting in a leaner and less investment intensive process Metrics: Taurus is listed on the Swedish stock exchange Aktietorget. 60 % of the shares are owned by a company by name Forskarpatent AB .Forskarpatent is owned by Swedish institutions and Universities the rest or 40 % of the shares are privately owned Web URL: taurusenergy.eu #31 Ceres Based in: 1535 Rancho Conejo Blvd., Thousand Oaks, CA 91320 Founded: 1996 Annual revenues 2009 (projected), 2008, 2007: Privately held company Type of technology: Gene Marker-Assisted plant breeding, biotechnology and other genonmics Fuel Type: Biomass is the common denominator to advanced biofuels, biopower and bioproducts and is independent of the end-fuel molecule. Major investors: Warburg Pincus, Warburg Pincus, Soros Private Equity Partners , HYPERLINK "http://www.gimv.com/"GIMV, HYPERLINK "http://www.oppenheimerfunds.com/"Oppenheimer. 3 top milestones for 2008-09 Launched commercial seed brand Blade Energy Crops, announced partnerships with leading biofuel and biopower companies. Established worlds largest energy crop trialing network. 3 major milestone goals for 2010-11. Ongoing commercial sales and scale-up in pace with industry. Business model: Seed sales and trait licenses Fuel cost (per gallons) Yields per acre is one of the single largest levers against feedstock costs, which typically represents 50% of the cost of the finished product. Competitive edge: Genetics, Intellectual Property, Early Mover Advantage Distribution, research, marketing or production partnerships or alliances. R&D: Texas A&M (leading sorghum genetics), Samuel Noble Foundation (Switchgrass genetics) and other unannounced alliances in miscanthus. Development stage: Commercial URL: HYPERLINK "http://www.ceres.net/"www.ceres.net and HYPERLINK "http://www.bladeenergy.com/"www.bladeenergy.com #32 Syngenta Based in: Schwarzwaldallee 215, CH-4058 Basel, Switzerland Year Founded: 2000 Annual Revenues: N/A, $11.6 bn, $9.2 bn Technology: Agronomics and Enzymes Fuel type: NA Major investors: 100% publicly quoted company 3 top milestones for 2008-09: Introduction of novel sugarcane planting methodology for improved sugarcane cultivation, harvest and yield under brand name Plene"!; Conducted full-scale commercial trials for Corn Amylase in 2008-2009; Further developed the use of tropical sugar beet in tropical regions with poor soil conditions, making particular progress in Colombia 9. 3 major milestone goals for 2010-11: Commercial launch of Plene"! by end-2010 Business model: Licensing of agronomic technology Fuel cost: NA Competitive edge: Excellent biotech competence in expressing enzymes in plants, and developing high yield varieties of corn and cane through enhanced germplasm, strong global R&D presence, and ability to integrate seeds and crop protection solutions Distribution, research, marketing or production partnerships or alliances: Partnership in Brazil with equipment manufacturers and millers for the novel cane planting methodology, variety of partnerships with ethanol producers in the USA for pilot test programs of Corn Amylase, multiple collaborations (public and private) aimed at stretching and improving our technological capabilities Development stage: Currently at pilot and demonstration stages of both Plene"! and Corn Amylase URL: www.syngenta.com #33 Aurora Biofuels Based in: 1201 Harbor Bay Parkway, Alameda, CA 94502 Business: Aurora burst onto the scene in June 2008 with the announcementthat it had raised $20 million in series A financing from Oak Investment Partners, Noventi and Gabriel Venture Partners. Gabriel and Noventi had participated in a seed stage round. Aurora plans to use technology developed by Berkeley professor Tasios Melis for an open-pond algae production system, and will produce biodiesel from algae. The company says that its process reduces the cost of biodiesel production by half, compared to current methods. Model: Owner-operator Past milestones: AlwaysOn named Aurora Biofuels in AlwaysOn 100. The company completed an 18-month pilot in early 2009, and VC backer Jim Long of Gabriel Venture Partners recently told a group of biofuels execs at Biofuels: Science and Innovation that algae was "the focus" at GVP as far as biofuels. In California, Aurora Biofuels announced that it has succeeded in optimizing its base algae strains to more than double CO2 consumption and fuel production, and has proven these results in an outdoor open system over the last several months. The company said that it has developed a proprietary process which allows for the superior selection and breeding of non-transgenic algae. Aurora Biofuels investors include Oak Investment Partners, Noventi Ventures and Gabriel Venture Partners. Aurora has made breakthroughs in extracting oil from algae without passing through a drying stage, bypassing the most expensive and energy-intensive part of the algae production process. Future milestones: Aurora is "highly confident" that it will reach targets of 6,000 gallon per acre yields and a cost of $1.30 per gallon" of algal fuel "at the gate", in its second generation of evolution. The company has raised $20 million which will carry it through the completion of a demo-scale 10-20 acre pond system by 2010. Metrics: Aurora leapt into the news this spring with a projected $1.30 cost for algae in its second-generation technology, due in 2013. Website: www.aurorabiofuels.com #34 Bionavitas Based in: 8469 154th Avenue NE, Redmond, WA 98052 Business: Bionavitas, based in Redmond, Washington, has developed Light Immersion Technology that enables the rapid, cost-effective production of algae for environmental remediation, manufacturing health and nutraceutical products, and producing biofuels. Model: Algal fuel developer and R&D partner in remediation and light immersion. Past milestones: In 2009, algae-to-energy pioneer Bionavitas unveiled its patent-pending Light Immersion Technology that dramatically increases algae yields in a cost-efficient and scalable model. Light Immersion Technology employs a system of light rods which extend deep into the algae culture. In external canal systems, the rods distribute light from the sun into the culture. This abundant and free energy source is ideal for generating large amounts of algae for use as biofuels. In closed bioreactors, the rods evenly distribute more readily absorbed red and blue spectrum light from high efficiency LEDs. While the LEDs increase the cost of production, algae grown in these systems are used for higher value markets such as nutraceuticals. Future milestones: In 2009, Blue Marble Energy and Bionavitas announced apartnership in which Blue Marble Energy will produce high-margin biochemicals from microalgae supplied by Bionavitas. CEO Michael Weaver has said that the company is looking at a site in Eastern Washington as well as throughout the Southwest for a location for its pilot-scale plant. Metrics: The Light Immersion Technology developed by Bionavitas fundamentally changes this equation by enabling the algae growth layer in open ponds to be up to a meter deep. This represents a 10 to 12 time increase in yield over previous methods that produced only 3-5 centimeters of growth. Website: www.bionavitas.com #35 Algenol Based in: Florida. Business: Algael fuel developer. Algenol explains that energy from the sun through photosynthesis produces simple sugars inside algae cells which, concurrently with enzymes, produce ethanol. Extremely fast growing algae renews the sugar supply. Model: Owner-operator and partner. Past milestones: in 2008, Biofields CEO Alejandro Gonzlez Cimadevilla said that the company is targeting 2 billion gallons of ethanol from algae by 2020 using the Algenol process. The company said that it considered 15 other locations in Mauretania, Algeria, Spain, and the US, before settling on Sonora because of its 328 days of annual sunshine and 3.75 million annual tons of CO2 emitted by local power plant CFE. The company said that it has purchased 22,000 hectares of unproductive land, and Gonzalez said that he will produce 250 Mgy by 2013, building off the recycling company, Grupo Gondi, founded by his father Luis Gonzalez Diez. Gonzalez has recruited Mateo Lopez, a former Mobil Oil senior construction executive in Mexico. The company secured an exclusive license for the Algenol technology until 2013 when the company reaches its 250 Mgy target. Future milestones: Algenol Biofuels and Dow Chemical will construct a $50 million pilot algae biofuels plant in Freeport. The plant will be located with Dow's existing chemicals complex, and will supply CO2 as well as land for the pilot algae facility. Dow said that it was interested in Algenol's ability to sue algae to produce ethanol, which could be used as a base for making ethylene, which is in turn a feedstock for many types of chemicals. The plant is designed to produce 100,000 gallons of ethanol per year at a target price of between $1.00 and $1.25 per gallon, according to Woods, who added that groundbreaking is expected to commence in 2010. Traditionally, chemical companies have been using natural gas as an ethylene feedstock. Algenol is among companies competing for a $25 million DOE grant. Georgia Institute of Technology, the National Renewable Energy Laboratory and the Membrane Technology & Research are partners in the project, which is targeting initial production of up to 140 gallons of algae fuel per day, or 51,000 gallons per year at a yield of 2,120 gallons per acre. The companies are jointly seeking a $25 million DOE loan guarantee. Metrics: According to CNN Expansion, Biofields has invested $30 million to date in the project, which is reporting yields of 6900 gallons per acre at its Sonora site. The company is said to be hiring 1500 temporary and 350 permanent workers and commenced construction in December. Algenol estimates the energy balance, i.e., the ratio of energy out vs. energy in will be greater than 8:1 which compares with 1.35:1 for corn ethanol. Website: www.algenol.com #36 Verenium Corporation Based in: Massachusetts Year Founded: 2007 (merger of Celunol and Diversa) Annual Revenues 2009 (projected), 2008, 2007 (in millions): FY 2007 $46,273 FY 2008 $69,659 FY 2009 Verenium will not be providing 2009 guidance at this time. Technology type: Fermentation, biochemical pathways Fuel type: Cellulosic Ethanol, a renewable fuel source produced from natural, non-food feedstocks, such as sugarcane bagasse, dedicated energy crops and wood products. Cellulose, a long-chain polysaccharide found in nearly all plant life, is the most abundant organic compound on earth. The Environmental Protection Agency says cellulosic ethanols high-oxygen content reduces carbon monoxide better than other oxygenates. Major Investors: AWM Investment Company Inc. Syngenta AG HealthCare Ventures LLC 3 top milestones for 2008-2009: Verenium begins commissioning nations first-of-its kind cellulosic ethanol demonstration plant in Jennings, Louisiana; Verenium announces plans to build first commercial cellulosic ethanol plant in Highlands County, Florida, with a target capacity of up to 36 million gallons per year (MGY); British Petroleum (BP) and Verenium form 50-50 joint venture (JV) to develop and commercialize cellulosic ethanol from nonfood feedstocks in the United States; JV now operates under the name Vercipia Biofuels 3 major milestone goals for 2010-2011: Secure financing for first commercial-scale cellulosic ethanol facility in Highlands County, Florida; Leverage R&D capabilities and enhance cellulosic ethanol capabilities; Pursue strategic partnership opportunities for the Specialty Enzyme Business Unit Business model:: The key elements of our corporate strategy are to develop integrated solutions for the emerging cellulosic ethanol industry for use in production facilities that we own and operate, individually or jointly with partners, as well as those of third-party licensees. We intend to use our leadership position to develop novel, high-performance enzymes and to advance our technology and process development capabilities, together with BP, at our pilot and demonstration-scale plants in Jennings, Louisiana, and our first planned commercial facility in Highlands County, Florida, to exploit opportunities in the developing market for the production of cellulosic ethanol. We have established our business model based upon the belief that owning and managing cellulosic ethanol production facilities in conjunction with strategic partners, including BP, will allow us to create economic value by incorporating our scientific and engineering skills into the production facilities. Through our joint venture with BP, we may also license our proprietary technology to extend our commercial reach and accelerate our market penetration. Establish a sustainable, high-growth, profitable specialty enzymes business. Our specialty enzyme products and product candidates target high-value applications where we believe our enzyme discovery and optimization technologies can deliver superior, proprietary solutions. We believe our combination of independent and partnered products is positioned to generate substantial product revenues at attractive gross profit margins. In 2008, we generated approximately $49 million in such revenues, an increase of nearly 90% over 2007. We hope to achieve increased product sales and profit margins to support the future growth and profitability of our portfolio of products sold directly by us and by our partners. Fuel cost: Our goal from a cost standpoint is to be producing ethanol that is competitive with todays grain ethanol (~$2/gal). Competitive edge: Verenium is the first publicly traded, fully-integrated, next-generation biofuel company, and its range of expertise and resources greatly enhances its potential for success. Verenium is mastering the entire cellulosic ethanol production process as the first and only company with the full range of field-to-pump capabilities. This includes: growing energy crops, developing enzymes, processing biomass into fuel and, ultimately, selling it. Additionally, Vereniums partnerships, which range from industry giants like BP and Syngenta to the U.S. Department of Energy (DOE), make the company uniquely positioned for success. We have a substantial intellectual property estate, including more than 250 issued patents and more than 350 patent applications, as of March 12, 2009. We believe that we can leverage our intellectual property estate to enhance and improve our technology development and commercialization efforts across both the biofuels and specialty enzymes business units, while maintaining protection of our key intellectual property assets. Vereniums technology enables conversion of nearly all of the sugars found in cellulosic biomass, including both five-carbon sugars and six-carbon sugars, into ethanol. This efficiency advantage, combined with low-input cost of cellulosic biomass, results in superior economics in the production of ethanol. Distribution, research, marketing or production partnerships or alliances: Alfa Laval (enzyme collaboration), BASF(enzyme collaboration), BP (commercialization of cellulosic ethanol), Bunge (enzyme discovery and development), Cargill (enzyme discovery and development), Danisco (enzyme discovery and development), DOE (cellulosic ethanol fermentation technology, enzyme development for breaking down biomass), Fermic (manufacturing of enzymes), Lykes Bros. (agribusiness), Marubeni Corporation (licensee), Scion (enzyme collaboration), Syngenta (enzyme cocktail collaboration),Tsukishima Kikai Co. Ltd. (construction of Osaka plant), University of Florida (fermentation organisms). Development stage: Verenium currently operates an integrated cellulosic ethanol pilot facility in Jennings, Louisiana. This plant is used to broaden the companys capabilities in advanced fermentation and to test a range of feedstocks for conversion into cellulosic ethanol. The pilot plant also serves as a real-time research and development facility to develop new enzyme cocktails for optimizing the production of cellulosic ethanol. Additionally, Verenium has fully commissioned its 1.4 MGY demonstration-scale facility, also located at its Jennings site, representing the first of its kind in the nation. Vereniums process technology has also been licensed to Tokyo-based Marubeni Corporation and Tsukishima Kikai Co., Ltd. and incorporated into their 1.4 million liter-per-year cellulosic ethanol plant in Osaka, Japan utilizing construction and demolition wood waste as a feedstock. Vercipia Biofuels, the 50-50 JV company between BP and Verenium, intends to break ground on one of the nations first commercial-scale cellulosic ethanol facilities in Highlands County, Florida, in 2010. This 36 MGY facility is expected to begin commercial production in 2012. Vercipia anticipates developing additional commercial facilities in the Gulf Coast region and expects to announce the location of its second plant in the coming year. Website URL:  HYPERLINK "http://www.verenium.com" www.verenium.com #37 Simply Green Based in: New Hampshire Business: Simply Green Biofuels was founded in November 2006 with the intention of offering green alternatives to home heating, diesel and marine fuel throughout the Seacoast. Model: Biodiesel, ethanol and bioheat distributor. Past milestones: In 2008, Simply Green Biofuels announced that it would open a "congreenience store", plus a biodiesel station in Dover. The company said that the station would be the first in the state to exclusively pump biofuels. B99 biodiesel will be available on advance request. In 2008, Simply Green Biofuels received the Maine Environmental Hero Award, which will be awarded at the Going Green Expo in Saco. The award was given in recognition of a bailout of 75 customers stranded in mid-winter without oil heat when conventional oil companies Veilleux Oil, Price Rite and Perron Fuels all went out of business. Future milestones: In 2009, Simply Green Biofuels will expand into Northern New Hampshire by opening a distribution center adjacent to the Clean Power Development facility to be built in Berlin.Start up burners within the facility, on-site equipment and back up building heat are applications for Simply Greens BioHeat and BioDiesel. According to Andrew Kellar, Founder of Simply Green, Our vision is to encourage loggers to replace traditional diesel used throughout the process- from the initial harvest to the transportation of wood to the facility, in order to have a truly environmentally friendly life cycle. Metrics: The SG station features B5 and B20 biodiesel, and E10 ethanol, while 75 percent of the products sold in the convenience store will be sourced within a 100-mile radius of Dover. Simply Greens is made from Waste Vegetable Oil (WVO). Blends are available from 5% up to 100% pure Biofuel. No system modifications are needed to run up to a 20% (B20) blend. Website: www.seacoastbiofuels.com #38 Carbon Green Based in: Illinois Business: Carbon services provider and ethanol operator. Model: Owner-operator. Past milestones: In 2008, Carbon Green said it expects to significantly increase carbon credit grants for US ethanol plants, following the first grant of credits to the 44 Mgy Corn Plus facility in Minnesota. The Corn Plus plant in Minnesota burns corn syrup to offset fossil fuel use, and uses two wind turbines for electricity. Future milestones: Carbon Green Bio Energy and AgStar Financial Services have entered into an agreement for Carbon Green to purchase the 40 Mgy Woodbury ethanol plant that was aquired by AgStar in the VeraSun bankruptcy. The plant was part of the US Bio group that was acquired by VeraSun last March before the company imploded over hedging difficulties and the collapsing price of ethanol. AgStar will continue to lead a group of lenders in financing Carbon Green BioEnergy. #39 SEKAB Based in: P.O. Box 286 SE-891 26 Ornskoldsvik, Sweden Year Founded: 1985 Annual turnover: 2009 (projected), 0,19 billion, 2008 = 0,22 billion, 2007 = 0,19 billion. Technology: Development of a Cellulose to Ethanol process based on Enzymatic Cellulose Hydrolysisafter dilute acid pre-treatmentandfermentation of C5 and C6 sugars. Fuel type: Ethanol Major investors: Regional Energy Companies Past milestones (08-09): 1.The commercial part of the company (Biofuels and Chemicals) developedand launcheda system for the first Verified Sustainable Ethanol together with Brazilian ethanol producers and the first part owned grain based plant in Polandsuccessfullystarted up in spring 2009. 2. Glucose yields from cellulose comparable to best lab results have been reached in the pilot for two stage dilute acid hydrolysis and more than 60 % of theoretical glucose yield has so far been reached for enzymatic cellulose hydrolysis of soft wood. 3. In a trial during spring 2009 the plant was run for 21 consecutive days without interruption and pentose fermenting yeast was successfully produced at a close to theoretical yield within the EU-project NILE. 3 major milestone goals (2010-11) 1. The internationalcommercial breakthrough for ethanol ED95 in modified diesel engines. 2. Secure finance for the development, preproject and precommercialisation phaseof cellulose ethanol. 3. First contract for a commercial scale plant Business model: Technology provider ina consortium with licensingof protected technology and supplier of design package. Fuel cost: The estimated cost based on bagass in tropical countries integrated with sugar based ethanol production is USD 2 per galloncomparable to sugar based ethanol. For softwood in Scandinavia with high feedstock cost it is, in an integrated plant with heat and power, about USD 3 per galloncomparable to agro-based production in the region. Competitive edge: SEKAB is one of the most experienced suppliers of ethanol based fuels with a broad portfolio of solutions from feedstock to vehicle, including how tomeet standards and regulations, overcomebarriers etc. Combined with the development of the cellulose based technology, the company iswellprepared for thecontinued expansion andfuture challenges. Alliances and Partnerships: SEKAB has experience to build distribution network together with other stakeholders like oil companies. The network for development includes major heavy vehicles producers, flexifuel vehiclemanufacturersin Europe, universitiesactive inthe field ofcellulose ethanol,researchenzyme companies for development and pilotevaluationof enzymes, equipment/reactor suppliers etc. Development stage: The technology is verified in the unique pilot plantoperated on shift 7/24since 2004, accumulated running time now exceeds 19 000 hours.Technologyis ready to be scaled up to the first commercial ethanol plant integrated with sugarcane based ethanol and/or heat and power generation plant for soft wood. Website: HYPERLINK "http://www.sekab.com/"www.sekab.com #40 Osage Bioenergy Based in: Virginia Business: Barley ethanol producer Model: Owner-operator Past milestones: Osage Bio Energy said that it would commence construction of its Congaree Bio Energy barley ethanol plant in Union County. Capacity for the $161 million project, one of four under development by the company and among the first barley ethanol plants in the world, was not disclosed. The company said that it will partner with Carlisle Finishing on the project, building the plant adjacent to the Carlisle Finishing textile plant, share a rail switch, and utilize steam from the textile plant. Osage Bio Energy received a $300 million investment commitment for its barley-based ethanol production plan. Texas-based First Reserve is providing the equity capital. The company's plan uses barley, a low-input winter crop in the Southeast, as a feedstock. Observers point out the higher production costs of barley ethanol and an indication from the USDA that its distillers grains may not be acceptable as livestock feed. The company indicated that two sites in North Carolina are finalists for its construction plan. Planned overall capacity was not disclosed, but the company's initial [plant in Hopewell, VA is slated for 55 Mgy. Osage Bio Energy received the go-ahead from municipal officials in December for its Hopewell plant. Ethanol experts had said the proximity of the town to the proposed plant raises the potential of smell and the traffic from trucks bringing in feedstocks, and the vote had been rated a toss-up by observers. Future milestones: Completion of the Appomattox Bio Energy plant, a 65 Mgy barley ethanol plant that will be the largest in the US using barley as a feedstock. Barley is a winter crop that can be double cropped with soybeans, and produces a high quality meal in addition to fuel ethanol. #41 Dynamotive Energy Systems Corporation Based in: 13091 Vanier Pl, Suite 140, Richmond, BC V6V 2J1 Year Founded: 1991 Annual Revenues: 2009 [projected], 2008, 2007) 2009 (n/a) , 2008 ($178,106) , 2007 ($0) Type of technology: Fast Pyrolysis, Biomass Into GasOil (BINGO) thru Hydroreforming & Hydrotreating stages. Fuel Type: BioOil, BioOil Plus, CQuest"! Biochar, UBA, UBB 3 top milestones for 2008-2009) " Renewable Gasoline and Diesel from Ligno-Cellulose Biomass Produced at Dynamotive's Research Facility in Ontario, Canada Re: Analysis of Dynamotive Upgraded BioOil Confirms Gasoline, Jet, Diesel and Vacuum Gasoil Fractions; Proprietary Two Stage Upgrading Process Provides Path to Mobile Fuels from Biomass BlueLeaf Inc. and Dynamotive Announce Biochar Test Results CQuest Biochar Enriched Plots Yield Crop Increase Ranging From Six to Seventeen Percent vs. Control Plots Dynamotive Receives $260,000 Order for West Lorne BioOil - The order envisages a minimum of 18 shipments of BioOil, August 3, 2009. 3 major milestone goals for 2010-2011 USDA ARS Study Results (Impact of Biochar on Soil Quality, Crop Yields, Carbon Sequestration, and Water Quality), Late 2009 Early 2010. Additional tests with BlueLeaf Inc. Pilot Plant Completion, Upgrading BioOil thru BINGO process. Third party testing/verification of fuel. Announcement of first U.S. project site for BioOil Upgrading plant (commercial/demonstration). Business Model: Licensing, Research & Development, Owner/Operator. Fuel Cost: BioOil: Fuel #2 BTU equivalent less 10% CQuest"! Biochar: Market value currently being developed thru independent trials UBA/UBB: Competitive Edge: " Food vs. Fuel: The Company converts residual biomass from agricultural and forestry operations and/or dedicated non-food crops through a thermochemical process into BioOil and Biochar. BioOil and Biochar plants can coexist with existing forestry and agricultural facilities, providing an additional benefit to operations. Yield: Dynamotives pyrolysis process converts roughly 85% of the total biomass feed into useful solid (char) and liquid (BioOil) fuels. The balance is utilized to provide energy to the process. Yields of Diesel/Gasoline from BioOil through the Stage 2 (hydrotreating) upgrading process of 37% have been achieved at bench-scale. The net overall yield from whole biomass to diesel/gasoline is approximately 25%, which to our knowledge is the highest ever reported. Scale: Dynamotives process is projected to be economically viable at 1/7 to 1/15 scale of competing technologies currently known or under development. It is projected that a plant processing under 70,000 tonnes of biomass a year would produce approximately 4,500,000 gallons of renewablegas-oil at under $ 2 per gallon. The scale factor enables distributed production i.e. plants can be developed in diverse locations creating sustainable green jobs, while being compatible with agro and forestry operations. Flexibility: the two stage process developed by the Company also allows for the opportunity to further upgrade the stage 1 renewable gasoil into diesel and gasoline fuels at a centralized facility or the development of a fully integrated plant if production logistics and economics merit it. This provides for flexibility in development and application. Investment: Given the plant scale, the investment required is comparatively low. Approximately $ 33 million will deliver a 15 year production capacity of approximately 67 million gallons of renewable transportation grade hydrocarbon fuels. This is a fraction of the capital cost per gallon and per plant required by proposed competing technologies. Time to market; Dynamotives pyrolysis platform is available today, with plants of 130 Mt and 200 Mt per day completed. The upgrading process uses conventional hydrotreatment equipment and process conditions allowing for rapid implementation at pilot and commercial scale 13. Distribution, research, marketing or production partnerships or alliances? Tecna S.A. (strategic engineering partner), Renewable Oil Corporation (Australia) 14. Development stage: Pyrolysis technology platform available commercially today, Upgrading BioOil thru BINGO process (bench-scale), pilot plant planned for 2010. Website http://www.dynamotive.com/ #42 Sustainable Power Based in: Texas Business: Renewable fuel and power producer, based on Rivera process. Model: Owner-operator, partner, licensor. Past milestones: Sustainable Power announced that in a three-month test conducted in the Dominican Republic, a Ford F350 hydrogen on demand system averaged of 40 miles per gallon, compared to a previous 8 mpg average with conventional fuels. Sustainable Power produces power and hydrogen as outputs from its biomass-based thermochemical conversion process. Completed an initial shipmentof its computer controlled "hydrogen on demand" Emissions Remediation Systems (ERS). The ERS produces hydrogen-on-demand from a mixture of water and a proprietary catalyst. The first ten units of an order for several hundred units has been shipped to the Dominican Republic for use on engines for power generation. Sustainable Power will share in the energy savings generated by the units. Partnered with Sustainable Produce to acquire Angel Eyes Produce of Massena, NY. Sustainable Power will produce electricity from biomass to power Angel Eyes Produce's Terraponics technology that grows fresh produce in "Super Grow Buildings," that utilize hydroponic and hydroculture technologies, and achieve a higher productivity than outdoor growing. Future milestones: Third-party validation of company data on yield. Metrics: The company said that it believes its technology can increase fuel economy in electrical generators by 30 percent. #43 ETH Bioenergia Based in: Brazil Business: Ethanol developer and producer, subsidiary of Odebrecht. Model: Owner-operator, JV partner. Past milestones: Signed a three year agreement with Braskem to supply 40 million gallons of ethanol to the petrochemical giant. ETH's management said that the off-take deal would take effect in the second half of 2010. Brazilian conglomerate Odebrecht will invest $581 million, via its ETH Bioenergia subsidiary, in three ethanol plants in Mato Grosso do Sul state. The plants will have a combined capacity of 15 million tons of sugarcane. The plants will manufacture sugarcane, ethanol and will produce energy from sugarcane bagasse. Future milestones: Two plants in Nova Alvorada do Sul will be ready for the 2009 and 2010 harvest seasons, while a third plant in Nova Andradina will be operational by 2011. This investment brings Odebrecht's holding to eight plants in Brazil. In 2008, Odebrecht agreed with Angola-based Sonangol and Damer to invest US$200 million in sugar ethanol and electricity projects in Malanje province. The project will cover 30,000 acres, of which 20,000 will be for sugar cane and the remainder for an ethanol plant and for crop rotation land. The joint venture will produce two million tons of cane, producing 160,000 tons of sugar, 50,000 cubic meters of ethanol and 140 megawatts of electricity per year. Damer and Odebrecht will each hold 40 percent of the venture and Sonangol will have the remaining 20 percent. The venture is known as Biocom. On schedule to increase its sugarcane crushing capacity from 3.6 million tonnes annually in 2008 to 45-50 million tonnes per year by 2016. The company also said that it expects to have more than $500 million in debt financing in place by December through the Brazilian national development bank (BNDES) for the construction of three proposed ethanol plants. The company aims eventually to have 10 mills in place by 2016 in Mato Grosso do Sul, Minas Gerais and Sao Paulo states. #44 Choren Based in: Germany Business: Biomass to liquids producer. Model: Owner-operator. Past milestones: Choren Industries and Norske Skog announced that they will jointly evaluate the potential for an advanced biofuels plant using wood biomass as feedstock for a synthetic biofuels process. Choren recently completed construction on a 4.5 Mgy demonstration biomass-to-liquids plant in Germany. Choren has said that it hopes to increase capacity at that plant to commercial scale of 71 Mgy. Volkswagen and Daimler acquired a minority shareholding in CHOREN Industries, a biofuels producer with a goal of producing 60 Mgy of BTL (biomass-to-liquid) second generation biomass-based synthetic fuel. Future milestones: Chorens plant in Freiburg - targeting 15,000 tonnes of biomass-to-liquid fuels is scheduled to open in early 2010, according to reports in Reuters and Lesprom. The plant utilizes wood products and wood-based waste, while a second planned plant in Schwedt will have a capacity of 200,000 tonnes. Metrics: CHOREN is currently building a beta plant in Freiberg site that will produce 4 Mgy. The company's target is 10-15 plants constructed by 2020 to reduce C02e emissions by 3 million metric tons. #45 OriginOil Based in: 5645 W. Adams Blvd. Los Angeles, CA 90016 Year Founded: 2007 Annual revenues: Undisclosed Technology type: Algae production process platform Type(s) of fuel produced Algae feedstock (lipids, biomass) Major investors. Accredited Investors only to date 3 top milestones for 2008-09. 2008  Helix BioReactor"!: patent filed for bioreactor technology that enables multiple vertical growth planes by optimizing delivery of light. 2009  Single-Step Extraction"!: patent filed for revolutionary simplification of the algae harvesting process; combines Quantum Fracturing"! with electromagnetics and pH modification to bring about oil extraction, and self-separation of oil, water and biomass. 2009  Live Extraction"!: patent filed for process that extracts algae oil on a continuous basis without cell sacrifice; allows a single algae cell to produce more oil during its lifetime using much lower amounts of energy; process can be used with genetically engineered algae for improved growth rate or lipid yield. 3 major milestone goals for 2010-11. 1. 2010: Pilot scale achieved for OriginOil production and extraction systems 2. 2010: First commercial customer 3. 2011: First implementation of a co-located system (wastewater treatment plant or similar) Business model: Technology Services, Device Sales, Licensing 11. Fuel cost: Standalone Algae Production: 1. Cost of Producing Lipid $5.47/g 2. Cost of Producing Biomass $4.53/g Wastewater co-located Algae Production: 1. Cost of Producing Lipid $4.57/g 2. Cost of Producing Biomass $3.79/g Competitive edge: Proprietary devices and processes for algae feeding, growth and harvest that help achieve industrial production of algae. Alliances and Partnerships: Idaho National Laboratory (DOE) Cooperative Research and Development Agreement focusing on process modeling, biomass logistics, and technology scaling. Desmet Ballestra  technology development partnership focusing on commercializing the Single Step Extraction"! System 14. Development stage: Pilot Website: HYPERLINK "http://www.originoil.com/"www.originoil.com #46 Propel Biofuels Based in: California Business: Biofuel retailer. Model: Owner-operator. Past milestones: Launched an improved version of its CleanDrive personal and fleet carbon emission reduction tracking platform. The application supports users tracking emissions benefits from biofuels usage for personal reasons, as well as those tracking emissions benefits for governmental reporting efforts, such as compliance with Californias 2020 Targets. The application also supports the future monetization of emissions reductions in carbon trading markets. The technology includes a widget that can be added to a company website or MySpace page. Hired Matt Horton, principal of venture capitalist @Ventures, as CEO of the company, replacing Rob Elam who will remain as President. Propel has E-85 ethanol and B-5 biodiesel pumps at five gas stations in Sacramento, Rocklin, Citrus Heights and Elk Grove. It also has biofuels pumps at six stations in Washington. Future milestones: In 2009, new Propel Biofuels CEO Matt Horton confirmed that the company intends to build as many as 500 renewable fuel stations throughout the state of California. The company recently relocated to California from Seattle and opened five biofuels stations in the Sacramento area. Propel Fuels intends to do so by striking up a partnership with Enterprise Rent-A-Car to fuel Enterprises rental cars in the Sacramento area with renewable E85 Flex Fuel. Enterprise has 73,000 flex-fuel vehicles nationally. Twelve Sacramento Enterprise locations have been selected to participate in the pilot program served by Propel's five Clean Fuel Points in the Sacramento area that serve E85 as well as biodiesel. Clean Fuel Points accept major credit and fleet cards and are open 24/7 offering convenience to Enterprise customers. #47 GEM Biofuels Based in: Madagascar Business: GEM BioFuels is initially focusing on the establishment of 'company managed' plantations of Jatrophatrees in Madagascar and the extraction of the vegetable oil that is produced from its seeds as this oil is well suited to use in the production of biodiesel. GEM BioFuels has been established to supply jatropha-based feedstock to the rapidly growing global biodiesel market. The Directors believe that one of the most significant potential constraints on the growth of this market is the relatively limited supply of biodiesel feedstock, and that this provides a significant commercial opportunity for the Company. Model: Owner-operator, in parnership with communes. Past milestones: Entered into 18 agreements with Communes in relation to 452,500 hectares of land suitable for the establishment of plantations in Madagascar, which provide it with the exclusive right to establish Jatropha plantations on theland. To date approximately 13,300 hectares have been planted. Future milestones: In addition GEM BioFuels has an agreement in relation to 40,000 hectares containing natural forest, including significant numbers of mature wild Jatropha trees. Separately, the Company also has informal arrangements with a number of individuals for the delivery of wild seed to the Groups storage facility. Metrics: The Company has secured 50 year agreements giving exclusive rights over 452,500 hectares (in excess of 1 million acres) to establish plantations, ranging in size from 2,500 - 50,000 hectares with a further 40,000 hectares of natural forest containing substantial numbers of mature Jatropha trees. #48 HeroBX Based in: 1540 East Lake Rd. Erie PA, 16511 Year Founded: 2006 Annual Revenues: $200 million Technology:- Transessterification Fuel type:- Biodiesel Major investors: Samual P. Black III Past milestones (08-09): Surpassed nameplate capacity of 45 million gallons. Selected fuel supplier to Green Flight (b100 flight Las Vegas Orlando), Perfected use of 15 feedstocks, reached profitability 3 major milestone goals for 2010-11 Execute 10 million gallon expansion,commercialize use of Camilina feedstock, execute algae investment , acquire 2nd plant Business model: Owner operator Competitive edge:- Multiple feedstock blending technology, Proprietary filtration systems, Logistics (rail, port, truck), Quality, Global reach Alliances and Partnerships: Logistics plus, Green Flight International, Desmitt Bellestra Development stage: Commercial Website: HEROBX.com #49 Cavitation Technologies Based in: California Business: Cavitation Technology is an engineering and manufacturing company, specializing inthe production of the biodiesel equipment. Its BioForce 9000 technology utilizes a patent pending flow-trough NANO cavitation technology (NCT) which reduces costs and time of biodiesel production process by 7-10 times. Model: Licensor. Past milestones: Signed Miura Engineering Co., Ltd. Tokyo, Japan ("MEC") (www.miura21.co.jp) as its new agent to serve markets in Japan for CTI's Nano-Cavitation Process Systems. Miura is a leading Engineering Company specialized in Edible Oil Processing Plants in the Far East. Announced a 3-for-1 forward stock split effective 10/29/09. CTI is a world leader in the development of technologies that represents a quantum leap over existing processing methods for a wide variety of applications and industries. Positioned to provide licensing and sales of its technology which can be applied to virtually every industrial fluid that requires complex molecular bonding, including large-scale water purification, removing impurities from agricultural based oils, biodiesel production, instant aging effects for alcoholic spirits, increased extraction of end product in crude oil refining, blending of bio-fuels as well as production of hydro-fuel (up to 15% water content yielding more efficient and cleaner burning) and much more. #50 Lotus/Jaguar Based in: England Business: Engine developer Model: Owner-operator. Past milestones: Lotus Engineering and Jaguar partnered to develop an advanced biofuel engine which they call Omnivore. The single-cylinder Omnivore engine will utilize multiple biofuels, including a new alcohol fuel to be announced by the team. A two-stroke process with injection of sustainable alcohols will enable to engine to obtain maximum efficiency. Software controls the compression ratio monoblovk construvtion (so separate cylinder head) allows for very high compression rations and cool high rpm running. Future milestones: Commercialization of prototype. Metrics: Can obtain higher MPG than straight gasoline using biofuels. Previously unranked companies of note Alkol Based in: 2711 Centerville Avenue Suite 400 Wilmington DE 19808 Year Founded: In Brazil in 1994. In the US in 2009 Annual Revenues: N/A Technology: Automobile ethanol conversion systems Fuel type: N/A Major investors: Self-funded Past milestones (08-09): 1 - Start operations in the US (achieved), 2 - Make media noise (achieved), 3 - Raise VC attention (achieved) 3 major milestone goals (2010-11): 1 - Develop US and Europe distributor dealership, 2 - close US$2 million in funding, 3 - close deal with US government to convert its fleet Business model: Owner Fuel cost: N/A Competitive edge:( 1  30 YEARS EXPERIENCE. The others have at best 3 years.( 2  TRANSPARENT to the end customer. The others require the user to install it himself and for that he needs to inform the fuel injector connector type, for example( 3  COMPLETE SOLUTION that will work with any car in any weather. The others depend on the installation of extra gasoline tanks for cold starts and are subject to sudden acceleration failures due to unhandled improper compression rates( 4  TOTALLY AUTOMATED. The others require the driver to choose a setting that either only works at idle or a high speeds (never both)( 5  EXCELLENT PRICE MARGINS. Because it is made in Brazil, where salaries are low, it s much cheaper than the US solutions( ( Alliances and Partnerships: In the process of closing down with a major fuel pump chain which will install our system in their facilities with personnel trained by us Development stage: Over 2000 units sold in Brazil the past 2 years. Fully mature technology employing Brazil's 30 years of ethanol technology Website: HYPERLINK "http://www.1hourflex.com/"www.1hourflex.com Allard Research Based in: 16276 County Road 616, Farmersville, Texas 75442 Year Founded: 2008 Annual Revenues: $1.1 MM Technology: Ethanol Mini-Refineries Fuel type: Ethanol Major investors: Self-Funded Past milestones (08-09): Shipping Worlds first ethanol mini-refineries, Computer controlled ethanol boiler systems, Modular ethanol systems 3 major milestone goals (2010-11) Cellulose front-end processor for mini-refineries, Feedstock sugar concentrators, Waste water cleanup systems Business model: Privately Owned Fuel cost: Varies by feedstock used Competitive edge: Standard components and production-line approach to lower cost, improve quality. Development stage: Commercial Avantium Based in: Zekeringstraat 29( 1014BV Amsterdam( The Netherlands Year Founded: 2000 Annual Revenues: 2007: EUR 15 million / USD 21 million 2008: EUR 19 million / USD 27 million 2009: not disclosed Technology: Chemical (heterogeneous) catalysis Fuel type: Components for diesel, kerosene and gasoline Major investors: Aescap (Netherlands), Capricorn (Belgium), DFJ Esprit (UK) 3 top milestones for 2009-10. Construction and operation of a pilot plant( Results of engine tests (diesel trucks and jet engines)( Results of material characterization (polyesters, with NatureWorks) 3 major milestone goals for 2010-12. Construction of demonstration plant( More and larger engine tests( More and larger tests for plastics (polyesters, nylons, polyurethanes) Business model: Fully owned: proof the chemical process to make our products and the basic properties of these products( Partnered: demonstration scale prodcution and large testing programs( Licensed: commercial production Fuel cost: EUR 1.2 - 1.5 (USD 1.7  2.1) per Gallon Diesel Energy Equivalent (so corrected for the same energy content as 1 gallon of regular diesel) Competitive edge: Catalitic conversion = continuous flow and short reaction times, so less steel (=capital) required than for biological batch processes( Excellent fit with the existing chemical infrastructure; the same process the (petro)chemical industry has used for decades( Disruptive economics for plastics, competitive economics for fuels Alliances and Partnerships: Royal Cosun: agricultural waste streams as feedstock( NatureWorks: application development of biobased polyesters Development stage Pilot Website URL HYPERLINK "http://www.avantium.com/"www.avantium.com Balboa Pacific Based in: San Diego, California Business: Balboa s  Green-Loop System is the worlds first waste to electricity AND biofuel system utilizing pyrolytic gasification. This game changing, zero waste system generates numerous environmentally beneficial by-products from any organic waste! Balboa Pacifics unique proprietary patented continuous-feed pyrolytic gasification waste treatment machine (the Bal-Pac) is capable of reducing the volume of ANY organic waste up to 95%, while producing recyclable and resalable by-products from the thermal destruction of ALL organic waste including: municipal solid waste, construction and demolition waste, used tires, biomass, animal waste, agricultural /agribusiness waste, forest waste, landscape waste, industrial waste, hospital waste, oil sludge, sewage waste, hazardous and toxic waste etc. Balboas pyrolytic gasification process is exceptionally clean, with emissions that are 99.999984% free of any dioxins, furan, smoke or soot while creating an inert, environmentally beneficial and usable by-product carbon char (an effective soil additive that retains moisture and nutrients while slowly releasing them into the soil). Bal-Pacs are modular, scalable (50-500tons per day) and mobile. Unlike incinerators or other combustion technologies, Balboas technology does not convert all organic matter into harmful CO2 emissions. Instead, pyrolysis, which is the destructive distillation of organic materials without oxygen, allows a significant fraction of the organic waste to be converted into carbon char, which is a form of activated carbon that absorbs moisture and nutrients, and thus qualifies as an effective way to sequester carbon. Accordingly, carbon char is both, a very useful soil additive for agriculture and a material that qualifies for carbon credits. Even though the United States is not a signatory of the Kyoto protocol, carbon credits are publicly traded worldwide and their value fluctuates around $18/ton of CO2 (i.e., about $66/ton of carbon). Model: Balboa will undertake a project specific, strategic approach to deliver its integrated systems to market. Balboa plans to build and operate its system on a project-specific basis, enter into joint ventures, build, operate and transfer, earning fees prior to transferring ownership, selling its systems outright, or on a royalty basis, when and where required. Past milestones: Numerous domestic and foreign patents issued with proprietary knowledge. A 50 ton per day machine was constructed, funded by Southern California Gas and private investors. Total investment: approximately $2.5 million dollars. Machine operated at California Steel for 18 months. During that time, numerous leading independent environmental companies like Dames & Moore (now owned by URS), Sandia Laboratories, Pacific Environmental Services, etc., tested and monitored emissions and char and without exception concluded that the Bal-Pac pyrolytic gasification process complies with all standards set by the US EPA and the worlds highest standards set by southern Californias AQMD. "Balboa's Pyrolytic Gasification destroys 99.999984% of the toxic elements found in ANY feedstock that was introduced through the System and is cost effective in its application to waste management." (URS study on website) In 2002 Balboa entered into a manufacturing agreement with Alstom Power Inc. Future Milestones: Balboa is currently in project specific negotiations with several private and governmental organizations both domestically and internationally. Domestically, one of the largest C&D recycling facilities will recognize substantial new revenue from the conversion of material once landfilled. The C&D facility owners are in negotiations with investors about replicating this C&D system at 30+ sites. The State of California is particularly interested in Balboas Green Loop System after discussions took place in Sacramento. California has energy and biofuel mandates Balboas technology will help California achieve. Balboas shovel ready waste to energy used tire project is currently seeking funding. This $5MM project has a 50% ROI! Because of NDA agreements in place, details about any international and some domestic projects cannot be revealed. Numerous projects, in addition to those mentioned above, are waiting to enter into negotiations with Balboa, once our proven technology has been in operation on a commercial basis. Metrics: The Bal-Pac is an excellent waste-to-energy machine. Balboa views landfills as oil companies view oil reserves, only Balboa will extract clean energy from the overflowing, energy rich landfills. Bal-Pacs improve global health by converting waste into clean electricity, reducing methane release from landfills (GHG), sequestering carbon, producing carbon char, and biofuel while generating substantial carbon credits. Waste is a $500 billion/year business worldwide primarily divided between landfills, incinerators and hauling services. Landfills are at maximum capacity with no municipality yearning for a new one in their backyard and incinerators are being phased out due to how dirty and expensive they are to operate. Balboas objective is to participate in the waste business by extending the life of all landfills indefinitely as well as replacing incinerators with Bal-Pacs. Additionally, by placing Bal-Pacs within waste transfer stations - waste could be reduced by up to 95% reducing the amount of waste requiring transport. Fewer trucks reduce transportation costs, the amount of vehicles on the road and exhaust pollution. Bioalgene Based in: Washington State 2008-09 ranking: Unranked Business: Bioalgene cultivates algae to remediate pollution, and to produce fuel and other bioproducts. The company has developed proprietary methods to accelerate algae growth, has proven those at pilot level in a coal-fired generating environment, and is developing distinctive approaches to harvest and convert algae. It is a participant in multiple consortia seeking development and commercialization projects and grants. Bioalgene is focused on cultivating algae to remediate pollution and produce bioproducts, including fuel. The company has developed proprietary methods to accelerate algae growth and is developing distinctive harvest and conversion systems. The vision that draws research scientists, entrepreneurs and investors to algae remains as important as ever: to replace a significant portion of petroleum fuels with the next generation of renewable alternatives. Bioalgene has developed phased processes to: Use algae to capture and convert air pollution -- particularly greenhouse gases Create profitable products from organic wastes Farm on a large scale in locations where raw materials are produced as wastes. Bioalgenes cultivation strategy is designed to minimize capital requirements and operating costs. Enroute to producing fuel, Bioalgene captures and converts CO2 today to generate voluntary carbon credits at high-volume industrial CO2 sources. The company has grown algae in a production environment, and accomplished fourfold growth acceleration using a proprietary approach that included flue gases from a coal-fired power plant. Bioalgenes strategic advantage to high-volume greenhouse gas producers include: Volume capture at low cost Anticipatory carbon credits Products from pollutants. The company creates value for customers and investors in three stages: Earning carbon credits from large-scale CO2 capture Producing fuel and products from algae grown at several facilities Producing and selling high-volume algae production systems. Bioalgenes approach to algae farming meets economic and environmental criteria, even in the midst of the recession. Plans include multiple sites growing high volumes of dense algae, using Bioalgenes strains, equipment and end-to-end systems. The companys triple-bottom-line global opportunity results from carefully planned and leveraged resources that provide substantial multipliers. Model: Project developer, strategic partner, service provider. Past milestones: Bioalgenes initial work to prove growth methods and economics engaged partners from Washington State University and Seattle University. Under a grant from Boeing, proved strain viability, growing conditions and yields from dozens of regional algae strains. Demonstrated volume, high-yield growth in open-ponds. Established its R&D center in Eastern Washington. Farmed algae in a production environment, accomplishing a fourfold acceleration in growth using flue gases directly from a coal-fired generating plant. Future milestones: Engineering and pilot phase expected in 2010 for a major Midwest industrial emitter of greenhouse gases. Algae will be used to capture and convert CO2 and other pollutants. Scale up algae production systems at the coal-fired generating plant where Bioalgene has previously captured CO2 and other GHG from flue gases in algae. Metrics: Based on our testbed and production level work, Bioalgene expects to convert each million pounds of CO2 into more than 10,000 gallons of fuel feedstock and 500 tons of bioproducts. BioFuelBox Based in:( 50 Las Colinas Lane( San Jose, CA 95119 Year Founded:( 2006 Annual Revenues:( ~$1M 2009( $0 2008( $0 2007 Technology:( Supercritical biodiesel production from waste fats, oils and greases Fuel type:( Biodiesel Major investors:( Element Partners( Draper Fisher Jurvetson Past milestones (08-09):( Scale technology 100x with first commercial plant( Produce premium biodiesel from true waste material (trap grease, DAF, etc.)( Sign up major fuel partner for off-take 3 major milestone goals (2010-11)( Roll-out additional waste-to-fuel plants( Optimize plant design and costs( Continue to qualify new waste feedstocks Business model:( Owner/Operator Fuel cost: Competitive with petroleum diesel Competitive edge:( Technology  when 90% of a gallon of biofuel is the cost of the feedstock, having a technology that can convert waste into fuel is imperative.( Business model  waste generators do not wish to become fuel experts, they just want to rid themselves of the waste and save money at the same time. BioFuelBox is a one-stop shop for their waste remediation.( Alliances and Partnerships:( Research  some technology licensed from US DOE( Development stage: Commercial Website:( HYPERLINK "http://www.biofuelbox.com/"www.biofuelbox.com  HYPERLINK "http://www.biomcn.eu/" BioMCN Based in: Netherlands 2008-09 rank: Unranked Business: Purification, evaporation and cracking (of crude glycerine) to obtain syngas which is used to synthesise bio-methanol 3 Top Milestones for 2008?09 March 2008: proof of principle in our 20.000 t pilot plant, October 2008: winner European Responsible Care Award, July 2009: successful start-up commercial 200.000 t plant 3 Major Milestone Goals for 2010?11 1. Selling bio-methanol on a large scale 2. Expanding current capacity, 3. Developing new technologies (possibly different feedstock) Model: Owner-operator. Quotable quotes: "The only company in the world to produce bio-methanol on a commercial scale. The solution to comply with biofuels regulations, chemically identical to regular methanol, great performance as a fuel." Blue Marble Energy Based in: 3408 Albion Place North Seattle WA 98103 Year Founded: 2005 Annual Revenues: 2009: $70,000 2008: $60,010.43 2007: $0 Technology: We produce biochemicals (esters, amides, anhydrous ammonia) and bioenergy through anaerobic fermentation and the manipulation of microbial environments. Fuel type: Clean burning natural gas (methane), anhydrous ammonia Major investors: Private Investors Past milestones (08-09): Completion of hybrid bench/demonstration testing; Closure of Series A Financing Round; Completion of 1 ton per day demonstration facility. 3 major milestone goals (2010-11) Commence construction of 33 ton per day commercial pilot facility; Begin delivery of esters to commercial partners; Closure of Series B Financing Round. Business model: Owner/operator Fuel cost: $1 mm BTU renewable natural gas; $0.63 per gallon anhydrous ammonia Competitive edge: BME has a distinct advantage with easily scalable, feedstock agnostic technologies, low to zero-cost inputs (waste biomass, naturally occurring microorganisms), and a range high value products including specialty and consumer biochemicals that are renewable, non-toxic and carbon-neutral. A broad product portfolio insulates BME from price and market volatility. Alliances and Partnerships: BME is creating a Renewable Alliance of clean tech companies that will be announced in the coming months. Development stage We have completed an initial pre-commercial demo site and are in the final stages of securing a pilot-to-industrial facility. Website: HYPERLINK "http://www.bluemarbleenergy.net/"www.bluemarbleenergy.net BP Biofuels BP Biofuels is a leading global biofuels player, with a breadth of investment that is unique in terms of both its scale and its reach. Producing ethanol today, BP Biofuels has investments throughout the entire biofuels value chain: from sustainable feedstocks, including cellulosic energy grasses, through to advantaged molecules like biobutanol. BPs close links into other sectors that will be crucial to the development of the biofuel industry, particularly the automotive industry, and its in-depth knowledge of the fuels market and infrastructure, will underpin the biofuels industrys intentions to grow to be a more material and sustainable part of the global transport fuel market. Since 2006, BPhasannounced investments of more than $1.5 billion in biofuels research, development and operations, and has production facilities operating or in the planning/construction phases in the US, Brazil and Europe. Our joint venture Tropical Bioenergia is producing ethanol from sugar cane in Brazil and represents the largest investment by any international oil company into the Brazilian ethanol industry to date. Vercipia Biofuels, our joint venture with Verenium, is progressing the development of one of the US's first commercial-scale cellulosic ethanol facilities, which will produce 36 million gallons of ethanol per year from energy grasses. In partnership with DuPont, BP is developing the advanced biofuel biobutanol and constructing a technology demonstration facility in the UK. Also in the UK, in partnership with British Sugar and DuPont, BP is constructing a110 million gallon per year wheat-to-ethanol facility. In addition, BP has invested $500 million over 10 years in the Energy Bioscience Institute (EBI), at which biotechnologists are investigating applications of biotechnology to energy. BP is one of the world's largest energy companies, providing its customers with fuel for transportation, energy for heat and light, retail services and petrochemicals products for everyday items. It is the largest oil and gas producer in the US and one of the largest refiners. BP also has a global network of around 22,000 service stations. BP blended and distributed more than 1 billion gallons of ethanol in 2008. 1. Company name BP Biofuels Based in: BP Biofuels UK Ltd County Hall Belvedere Road London SE1 7BF Year Founded: BP Biofuels was set up in 2006. BP p.l.c. celebrates its centenary in 2009. Annual Revenues: BP does not disclose the revenues of individual operating businesses. All our Alternative Energy results are reported as part of Other Business and Corporate in the group's results. Technology: The BP Biofuels strategy focuses on the fermentation of sugars to produce ethanol, biobutanol and biodiesel. Fuel type: BP has a number of strategic biofuel investments: BP is producing ethanol from sugar cane in Brazil in a joint venture with Maeda and Santelisa Vale, called Tropical Bioenergia. The JV will invest approximately $1 billion in two refineries, each of which will have a capacity of 115 million gallons. In partnership with DuPont, BP is developing the advanced fuel molecule biobutanol, which has a higher energy content that ethanol, can be blended at higher rates into fuel that can be used by vehicles on the road today and may be able to facilitate the adoption of biofuels into the fuel supply chain at a faster rate. The partners are constructing a technology demonstration facility in the UK. With British Sugar and DuPont, through a joint venture called Vivergo Fuels, BP is constructing a 110 million gallon-per-year wheat to ethanol plant in the UK. When operating next year, it will produce one-third of the UKs requirement for ethanol under the UKs renewable transport fuel obligation (RTFO). Once the technology has been proven at scale, the partners will look to convert the plant to produce biobutanol. In partnership with Verenium, BP is working to develop and commercialize advanced lignocellulosic biofuels, from energy grass feedstocks. The joint venture, Vercipia Biofuels, will be constructing one of the first cellulosic ethanol facilities in the US, based in Highlands County Florida. When operating in 2012, the plant is expected to produce around 36 million gallons per year. In August 2009, BP announced a joint development agreement with Martek Biosciences Corporation to advance technology for the conversion of sugars into biodiesel. BP has invested $10 million investment. The technology will convert sugars derived from biomass feedstocks (such as sugar cane or dedicated energy grasses) into diesel fuel molecules. BP has committed $500 million over 10 years into the Energy Biosciences Institute working with the University of California Berkeley and its partners, the University of Illinois, Urbana Champaign and the Lawrence Berkeley National Laboratory. The institute is exploring ways in which biosciences can be applied to produce new, cleaner energy fuels, including advanced biofuels. BP is working with Mendel Biotechnology to develop a range of new energy grass feedstocks that can be used to produce the next generation of advanced cellulosic biofuels. Major investors: BP is a public company, of which BP Biofuels is a wholly-owned subsidiary. Past milestones (08-09): Production of bioethanol from sugar cane: First production at Tropical Bioenergia, Brazil, in September 2008 Development of lignocellulosic biofuels: Technology partnership with Verenium formed in August 2008 to develop and commercialise cellulosic bioethanol technology based off energy grasses such as energy cane and miscanthus. February 2009: joint venture with Verenium created (Vercipia Biofuels) and plans to construct a 36 million gallon per year commercial-scale cellulosic bioethanol plant in Highlands County, Florida, announced. Sugar-to-diesel technology: Joint development agreement (JDA) between BP and Martek Biosciences Corporation announced August 2009. JDA will establish proof of concept for large-scale, cost effective microbial biodiesel production through fermentation, from biomass feedstocks. 3 major milestone goals (2010-11) With our JV partners: Advance the demonstration of biobutanol technology: Complete construction and begin production at a biobutanol technology demonstration plant in the UK (with our partners, DuPont). Begin construction of one of the USs first cellulosic ethanol facilities, in Highlands County, Florida (with our partners Verenium Corporation). Progress development of sugar-to-diesel technologies in partnership with Martek Biosciences Corporation. Business model: BP operates primarily through joint venture and joint development partnerships with other organizations that have expertise in the technologies and markets required to ensure success. BP brings scale, infrastructure and fuels market knowledge to these partnerships to drive long-term development of the businesses. Fuel cost: Varies for each of our technologies. We aim to bring biofuel costs down to a level at which they are competitive with conventional fuels without subsidy. Competitive edge: BPs contribution to the biofuels industry is significant and growing. For our own biofuel operations, our differentiators are: Global scale and reach, and an intent to develop projects that can succeed on a global platform and make a material difference to supplies of sustainably-produced biofuels. Breadth of strategy covering the entire biofuels value chain, from a range of sustainable feedstocks appropriate to different markets, through to the production of advantaged molecules to meet varied consumer needs: ethanol, biobutanol and biodiesel. As one of the worlds largest energy companies and a major blender, distributor and retailer of transport fuels, BP has core expertise and capabilities in fuel infrastructure, fuel markets and the requirements of the vehicle parc. This experience will be crucial in scaling-up the biofuels supply chain to meet the needs of consumers. Sustainability has been central to the strategic decisions that BP has made about its biofuels business: the feedstocks to invest in, the geographies to focus on and the molecules to pursue. We are developing ways to ensure and report on sustainability throughout our supply chain including the development of an effective sustainability management system for our biofuels operations and we are members of the Roundtable for Sustainable Biofuels, the Better Sugarcane Initiative, Roundtable for Sustainable Palm Oil and Roundtable for Responsible Soy. Alliances and Partnerships: Major joint venture / joint development partners in the biofuels area are: DuPont British Sugar Verenium Corporation Mendel Biotechnology Martek Biosciences Corporation Santelisa Vale Maeda Group The Energy Biosciences Institute Development stage Commercial production of bioethanol from sugar cane in Brazil. Commercial production of bioethanol from wheat under construction in the UK. Demonstration scale LC ethanol (through our partners, Verenium) and planned construction of commercial-scale facility in Florida. Biobutanol technology demonstration facility under construction in the UK. Website URL  HYPERLINK "http://www.bp.com/biofuels" www.bp.com/biofuels Chemrec Based in: Sweden, US subsidiary based in Illinois. Year Founded: 1989 Annual revenues 2009 MSEK 40 million 2008 MSEK 32 million 2007 MSEK 20 million Type of technology The technology is gasification of black liquor for syngas generation followed by fuel synthesis. Black liquor is an abundantly available liquid biomass feedstock (600 TWh per year globally) with unique gasification properties allowing single step gasification to raw syngas of high quality (very low methane and tar content). In addition to supplying syngas the gasification process simultaneously provides chemicals recovery capacity for the host pulp mill cutting the effective investment cost significantly Type(s) of fuel The type of fuel is flexible since the route is over syngas. Preferred fuels from a technical and economic standpoint are methanol and DME (dimethyl ether) which are the fuels produced with highest yield, energy efficiency and GHG emission reductions and with the lowest product cost on an energy content basis (regardless of which type of gasification front-end is included). In the extensive well-to-wheel joint study by the research institutes European auto industry (EUCAR), refinery industry (Concawe) and European Union (JRC), the combination of black liquor gasification and these fuel products were identified as the most energy-efficient and having the highest greenhouse gas emission reduction among the multitude of fuels studied. Major investors VantagePoint Venture Partners, Environmental Technologies Fund, Volvo Technology Transfer, Nykomb Synergetics 3 top milestones for 2008-09. Created the BioDME consortium (Volvo Trucks, Total, Preem, Haldor Topsoe, Delphi, ETC and Chemrec) and completed financing for the BioDME technical demonstration project. The project includes development and production of heavy truck test fleet based on DME fuel, production of BioDME from black liquor derived syngas and putting in place of fuel distribution and filling stations. The production plant is located in Pite, Sweden, project implementation activities well under way. Roll-out of first truck is in Sept 2009 and BioDME production will start July 2010. Created full-scale production plant concept for the Domsj biorefinery and pre-qualified the project for $65 million investment grant from the Swedish Energy Agency. The plant will produce 95000 tonnes per year of BioDME with the capability of also producing green methanol. Total investment cost is approx. $350 million. Accumulated operating time in the 20 tonnes dry solids per day DP-1 pressurized (30 bar, 450 psi), oxygen-blown development unit reached 10000 hours in June 2009 consistently producing good quality syngas and recovered cooking chemicals. Scale-up activities for the 25 times larger commercial gasifier and gas cooling units are being essentially complete before end of 2009. 3 major milestone goals for 2010-11. Successfully complete, start up and operate the BioDME plant Completing FEED and closing of financing for Domsj project for start-up early 2013. Develop additional projects in Europe and North America Business model: Project development, technology licensing and plant co-ownership. Fuel cost: Full fuel cost including capital cost as per RENEW project definition at $2 per gallon diesel equivalent ($1.5 per gallon ethanol equivalent) at the current US SE forest biomass price level. Generally, to get comparable and realistic answers to this question a standardized calculation model is required. There have been many grossly misleading statements on fuel cost circulating, especially in the US, where the numbers have been based on assumptions of negative feedstock costs or unrealistically low capital costs. Competitive edge: Well-developed technology with tens of thousands of operating hours in commercial first-generation plants and extensive relatively large-scale pilot tests for pressurized, oxygen-blown. Fuels synthesis is using fully commercial technology from the petrochemicals industry. BioDME plant under erection. Well-documented low product cost and high GHG reduction (approx. 94%) as documented in open studies by e.g. Princeton university, EUCAR/Concawe/JRC and RENEW. The technology will enhance value of existing assets and safeguard existing jobs in the pulp and paper industry while investment and operating costs are reduced by shared functions. Distribution, research, marketing or production partnerships or alliances. BioDME Consortium for realizing the BioDME project Haldor-Topse, technology cooperation Alstom, development agreement Development stage: Demo for motor fuels units Commercial for first generation air-blown gasifiers URL: www.chemrec.se Chemtex Italia srl M&G Group Address: Localita Ribrocca snc 15057 Tortona (AL) Italy R&D Center: Strada Savonesa 9 Fraz. Rivalta Scrivia 15057 Tortona (AL) Year Founded: M&G is a family-owned company headquartered in Tortona, Italy, founded in 1953 by Vittorio Ghisolfi. It originally manufactured packaging for detergents and toiletries, mainly from HDPE and PVC. Today is the largest private owned chemical company in Italy. In 2004 the group purchased Chemtex International Inc. from Mitsubishi Corporation, acquiring all its engineering, project implementation and business assets. As a result M&G Group joined in the business of engineering, procurement and construction management in the fields of polyester (fibers and polymers), refining, petrochemicals, specialty chemicals and biofuels extending its presence to China and India Annual revenues: 2.5 Billion $ in 2009 (projected), 2008 2,7 Billion $ and 2007 2.5 Billion $. Type of technology(s): Pretreatment with steam explosion. Enzymatic Hydrolysis and Fermentation Type(s) of fuel Type: Second generation bioethanol (from lignocellulosic biomass) Major investors. M&G group 100% family owned company Major milestones for 2008-09. 1- Agronomic field activities: Our research has selected best energy crops with the following characteristics: High-yielding species (> 40 ton/ ha of dried biomass) High biomassbioethanol conversion ( >10 ton/ha) Low input requirements biomass (minimization of fertilizers and water) Optimization of agronomic systems (cultivation - logistic transportation) 2 Development activities: Pretreatment. M&G has developed a new pretreatment process based on an evolution of steam explosion Since June 2009 a continuous pilot plant (1ton/day of dried biomass) is in operation at Rivalta R&D center in Italy Hydrolysys and fermentation Definition of best enzyme package for selected and pre-treated biomass. Modeling and development of high solid concentration enzymatic hydrolysis Novel Hydrolysis Set Up Hydrolysis reactor design and scale up Major milestone goals for 2010-11. - Main objective: Developing a complete crop-to-ethanol value chain through a conversion technology able to transform selected ligno-cellulosic material into bio-ethanol in a sustainable way. - Construction of industrial demo plant (40.000t/y) in 2010 - 2011 - Scale-up to industrial plant and commercialization of technology (2012- ..) Business model Build first industrial plant and license the technology (selling relevant engineering and key equipment as minimum scope) Fuel cost: Ethanol cost competitive with gasoline cost with oil at 45USD/bl or higher Competitive edge: Integrated solution including support on agronomic development and supply chain management, low cost solution and possibility to produce ethanol competitive with gasoline Distribution, research, marketing or production partnerships or alliances. Many alliances with industrial and academic partners but cannot be disclosed unless specific agreement are in place. Stage Actual : Pilot Plant in operation (able to treat 1ton/day of biomass), Industrial Demo (40,000 t/y EtOH) under engineering phase. Website URL. www.gruppomg.com www.chemtex.com Clean Emission Fluids Address: Detroit, MI 48202 Year Founded: 2007 Annual revenues: $0 in 2007, $20,000 in 2008, $345,000 in 2009 (projected), $3.45 million in 2010 Type of technology(s) High-quality ASTM Variable-ratio Biofuel Micro-Blending for ease of on-site, on-demand fuels with iFAST Network on tracking fuel economy and cost-reductions based on feedstock and concentration to enable mass acceptance. Fuel Type: Involved in storing, blending and dispensing : Biodiesel, Ethanol, Biobutanol and Diesel Exhaust Fluid (DEF) Major investors. Automation Alley, Troy, MI + private angel investors. Seeking $3 million additional. 3 top milestones for 2008-09. 1. Development of technology in 2008. 2. Commercial readiness in 2009 Q1. 3. Commercial Sales in 2009 Q2. 3 major milestone goals for 2010-11. 1. Develop Production Center. 2. Scale production to 100 units in 2010, 400 in 2011. 3. Adding Biobutonal, vegetable oil (100%) fuels + other fuels/fluids. Business model: Manufacture direct sales and distributorships. Fuel cost: $1.75 to $4.50 /gal. Competitive edge(s): Enabling lower Biofuel (i.e. Biodiesel) price at the pump for consumers, simplifying supply chain, to enable mass acceptance. Distribution, research, marketing or production partnerships or alliances. Currently pursuing and securing distribution agreements with major suppliers. Stage: Commercialization. Website URL. www.cleanemissionfluids.com and www.dieselexhaustfluid.com Codexis Based in: 200 Penobscot Drive, Redwood City, CA 94063 Year Founded: 2002 Annual revenues: Codexis is a private company and does not disclose revenue. Type of technology: Codexis manufactures industrial biocatalysts for use in creating faster, more efficient and environmentally-friendly manufacturing processes in the bioindustrials and pharmaceuticals markets. Type(s) of fuel produced Next generation, advanced cellulosic biofuel from non-food sources Major investors Bio*One Capital Chevron Technology Ventures CMEA Capital Maxygen, Inc. Pequot Ventures Pfizer Shell 3 top milestones for 2008-09 January 23, 2008 Announced the opening of its fermentation laboratory in Budapest, Hungary; a research center of excellence in fermentation strain development and process technology supporting Codexis Bioindustrials March 10, 2009 Announced an expanded agreement with Royal Dutch Shell plc to accelerate commercialization of next generation biofuels May 12 and January 7, 2009 Announced commercial agreements with Teva Pharmaceuticals and Roche using Codexis pharmaceuticals research productivity technology 3 major milestone goals for 2010-11 Continue progress in biofuels development collaboration with Shell Initiate a major partnership in the carbon capture market. Continue to move towards profitability and building a sustainable company Business model: Codexis is a clean technology company focused on applying a proven, robust innovative platform that helps Based in: global efforts aimed at curbing climate change. Codexis programs include advanced biofuels development and commercialization with Shell, near-term expansion into carbon capture markets from coal-fired power plant emissions, and longer term expansion into water treatment and clean chemical manufacturing. The company designs and develops advanced enzyme products for customers in the bioindustrials and pharmaceuticals industries. In addition, the company generates sales from sales of biocatalysts, intermediates and Codexis Biocatalyst Panels in the pharmaceuticals industry. Fuel cost: n/a Competitive edge: Proven, commercialized clean technology Codexis technology platform allows the company to quickly develop biocatalysts suitable for commercial scale and enables development of biocatalysts with improved performance characteristics rarely present in naturally-occurring biocatalysts. Multiple major target markets and global customers Codexis proven biocatalyst technology is presently used by Shell to develop biocatalysts to produce advanced non-food transportation biofuels. Future bioindustrial markets of interest include carbon management, water treatment and chemicals. It is also in use on a commercial scale in the pharmaceuticals industry in companies such as Merck,Pfizer and Teva. Capital-efficient business model Codexis business model leverages its collaborators engineering, manufacturing and commercial expertise, distribution infrastructure and ability to fund commercial scale production facilities. Diversified and visible revenue base Codexis revenue stream is diversified across various industries, with revenues derived from biofuels development and the pharmaceuticals markets. Future markets include carbon capture, water treatment and chemicals. Distribution, research, marketing or production partnerships or alliances Shell Merck Pfizer Roche Teva Development stage: Development Website URL HYPERLINK "http://www.codexis.com"www.codexis.com Comet Biorefining Based in: 737 Guildwood Boulevard, London, Ontario N6H 5G2 Year founded 2009 Annual revenues 2009 (projected) under $1 MM Type of technology Pretreatment; Comet Biorefining has developed a transformative technology to produce cellulosic sugar from biomass for the production of biofuels and bioproducts. Type of fuel produced Comets cellulosic sugar can be used to produce any biologically derived fuel, including ethanol, butanol, synthetic hydrocarbons, algal fuels. Major investors Internally funded Top milestones accomplished in 2009 Proof of concept at lab/pilot scale Patents filed Co-location site for demonstration facility identified Top milestones for 2010/2011 Financing Construct/optimize demonstration facility and design commercial system Establish downstream partnerships and licensees Business model License cellulosic sugar production technology; royalty-based payments Competitive advantage Low cost sugar; as low as 7 cents/lb Stage Pilot stage Url  HYPERLINK "http://www.cometborefining.com" www.cometborefining.com Continental Bio-Refineries Address: Vancouver, BC Year Founded: 2009 Annual revenues :pre-revenue Type of technology(s) Thermochemical dehydration Fuel type: Polymeric Carbon Bio-Fuel (Synthetic Coal). Energy Density from 18 to 30 GigaJoules / tonne Major investors. Alexis Fosse Mackintosh, Jerome De Luca, Chris Roberts 3 top milestones for 2008-09. 1. Complete the construction of the 20 litre (12kg) tandem bio-refinery for the production of Solid PolyCarbon Bio-Fuels from non-recyclable paper waste. Completed September 5, 2009. The testing of product produced from a variety of feedstocks is ongoing. 2. Confirmation that International bio-fuel standards exist, Lab tests confirm compliance and verifying trials with various waste streams continue 3. Complete engineering and design studies for a 5 tonne bio-refinery to be built in 2010 and to complete construction of a laboratory scale engineering model. 3 major milestone goals for 2010-11. 1.Design and build a tandem 5 tonne Solid PolyCarbon Bio-Fuels bio-refinery to test the commercial feasibility of the intellectual property in the two patents licensed from EveGenetics Canada. The design and construction is underway and expected completion Spring 2010. 2.Design and build a 100 tonne a day to Solid PolyCarbon Bio-Fuels plant to convert cellulosic waste from an Ethanol Plant to synthetic coal to provide fuel to Ethanol Plant. Revenues from the demonstration plant will be used to commercialize the technology and support further research. Expected completion Q4 2010. 3. Develop closed loop waste to energy model for commercial settings eg. Greenhouse operations to use waste to produce synthetic coal to fuel boilers and to recapture CO2 increase vegetable yields. Business model Design, build and operate as joint ventures and limited partnerships. Fuel cost: Cost to produce fuel will be approximately $40 CDN / Metric Tonne Competitive edge(s): Waste diversion from landfills resulting in better methane gas mitigation, operators using synthetic coal will receive carbon credits since synthetic coal is newly fixed as a closed sequestered carbon. Stage: 10 Tonne/Day commercial-scale demonstration bio-refinery Website URL. HYPERLINK "http://www.continentalbiorefineries.com/"www.continentalbiorefineries.com Continental Technologies 2. Address: Headquarters: 4635 Nautilus Court South, Boulder, CO 80301 3. Year Founded Continental Technologies was founded in late 2007 in Ponca City, Oklahoma to service the pilot plant needs of the energy and chemical industries with a unique value proposition the entire staff has come from large company R&D departments so that the design and fabrication focus is from the end-users perspective. In addition, pilot plants are not a filler; they are what the company does. Continental Technologies is the only pilot plant fabricator who offers an option to operate the pilot plants at its facilities. Finally, Continental Technologies sister company, Eltron Research and Development, is a 27-year old, 50-employee company that can be utilized to augment the clients development capabilities. 4. Annual revenues 2009 (projected), 2008, 2007 Confidential. 5. Type of technology: Continental Technologies specializes in pilot plant fabrication, focusing on fuels (including synthetic and biofuels), catalysts, chemicals and polymers process technology development and scale-up. The company has experience with equipment for virtually every fuels relevant process gasification, pyrolysis, hydrotreating, fermentation, Fischer Tropsch synthesis, transesterification as well as catalyst development, hydrogen production and chemicals development. The companys suite of services includes fabrication, design, engineering, installation, training, documentation and operation.Continental Technologies has had several customers tell them that their ability and willingnessto operate pilot plants for clients and the capability to train their operatorsare significant advantages. 3 top milestones for 2008-09 Continental Technologies recently completed their first major job, with the leading company in the U.S. for biomass and coal conversion to liquid fuels. Continental Technologies designed and fabricated six reactor systems and provided startup services and training. Continental Technologies moved into their new 34,000 square foot fabrication facility, located in Ponca City, Oklahoma. The facility is near major highways and rail routes and features high bay workspace, five-ton and ten-ton overhead cranes and areas designed for unit testing and operation. Continental Technologies completed three more jobs after moving into the new fabrication facility. The company is well-positioned to assist clients in the rapidly-expanding biofuels area to scale up their technologies. 3 major milestone goals for 2010-11 To participate meaningfully in the alternative energy business by helping companies scale-up their technologies. To triple Continental Technologies workload. To operate a plant in-place that we built for a client. Business model (e.g. licensing, owner/operator) Engineering Design/Fabrication/Operation Services provider Fuel cost (per gallons) NA Competitive edge: Continental Technologies core staff previously worked in the R&D departments of big oil companies, designing, building and operating pilot-scale process equipment for 20+ years. The combination of this technical expertise with hands-on operation experience enables Continental Technologies to approach each project from the users perspective building each unit as though they will be running it themselves. The result is a unit built by operators, for operators that is easy to operate and maintain while providing the data and product essential to optimizing processes. Safety is a foremost design principle and Continental Technologies experience and training allows them to contribute to formal safety review and compliance with industry standards and regulations. Customers can save an estimated 20% by choosing to have Continental Technologies experienced staff operate their pilot plant where it is fabricated in Continental Technologies fabrication facility. This is possible because the equipment won't need to be skid-mounted, shipped or installed, cutting costs and speeding time to operation. Continental Technologies will gladly host a customers team of operators as well, providing as much assistance and training as is requested. No other pilot plant designer or fabricator offers this capability. Oneuniqueadvantage that Continental Technologies hasversusits competitors is a close working relationship with Eltron Research & Development, an organization with over 25 years of experience in catalyst design, synthesis, evaluation & scale-up, materials research & synthesis, design & engineering, analytical services, prototype development, and technology feasibility studies. Engaging Eltron can help speed time to market and reduce risks associated with introducing new technology. In essence, Eltrons Ph.D. scientists and engineers are an "instant R&D" team that's ready to complement your in-house staff and help you adjust to industry trends. Distribution, research, marketing or production partnerships or alliances NA Stage (e.g. seed, pilot, demo, commercial) Continental Technologies is a commercial entity. Website URL HYPERLINK "http://www.contechfab.com/"www.contechfab.com Diversified Energy Based in: 2020 W. Guadalupe Road, Suite 5 Gilbert, AZ 85295 Founded: 2005 2009 annual revenues (projected) = $500k 2008 annual revenues = $500k Business: Diversified Energy Corporation is a renewable and alternative energy technology development and commercialization company. The strategy of the company is to maintain a diverse portfolio of technologies in the gasification and biofuels markets. As such, the company is developing (1) an innovative molten-slag based gasifier [OmniGas"!] that can gasify a wide range of feedstock and produce an ultra-clean syngas, (2) a biorefinery technology to covert non-food based oils to petroleum-equivalent transportation fuels using little net hydrogen [Centia"!], (3) a glycerol burner for the production of heat and/or power using raw crude glycerol from transesterification-based biodiesel production, and (4) a low cost algal biomass production system [Simgae"!]. The company has been the recipient of numerous government grants and private investment to develop and ultimately commercialize these technologies. Technology: From OmniGas"!  syngas and/or various outputs from the further processing of the syngas (e.g., natural gas, FT diesel, methanol, ethanol, chemicals, and electricity) From Centia"!  biojet fuel, renewable diesel, and biogasoline all similar to petroleum- derived fuels From glycerol burner  heat and/or power From Simgae"!  algal biomass, lipids, nutraceuticals, and animal/fish feed Investors W. David Thompson (founder) and private individuals. Company is privately held and funded, no venture capital or institutional funding. Past milestones: a) Capture of multiple Small Business Innovative Research (SBIR) contracts from the DOE and DoD to develop the OmniGas"! molten-slag gasifier at a scale of 1 ton/day, as well as a R&D grant award from the California Energy Commission. b) Successful production of sample batches of renewable diesel from Centia"! biorefinery process under a grant from the state of North Carolina. c) Successful fabrication and operation of a 90k Btu/hr crude glycerol burner prototype, including testing for emissions and use of glycerol from operational biodiesel plants. Future milestones a) Successful demonstration of OmniGas"! reactor at 1 ton/day, construction start for full- scale, commercial equivalent pilot-plant facility. b) Design, integration and demonstration of a 20  50 gallon/day Centia"! system taking multiple inputs (algal oils, jatropha oils, and animal fats) and producing biogasoline and biojet fuel with little net hydrogen consumption. c) Scale-up of crude glycerol burner to 2 MW class, first commercial orders received. Business model Diversified Energy has a business model that is capable of reacting to the market environment and the situation at hand. The company requires additional capitalization to complete the development and commercialization of its technologies. Dependent upon the source of that funding, the company is open to sublicensing its technologies, forming JVs, spinning out the IP into new entities, selling its IP, building and selling plants, and/or building and operating plants. Fuel cost: OmniGas"! syngas estimate is $4.00 - $6.00/MMBtu. Centia"! estimate is <$0.40/gallon plus the cost of the incoming feedstock. Competitive edge: Diversified Energy s competitive advantage is in its suite of innovative technologies, all of which have a common set of powerful, value-added attributes including: 1) technologies that can accept multiple incoming feedstocks, 2) technologies that can produce fuels that look akin to fossil-fuel based products, and 3) technologies that can economically scale to various sizes and thus bring distributed applications in close proximity to feedstock sources and energy distribution nodes. Stage: Pilot URL: www.diversified-energy.com Drystills COMPANY INFORMATION Based in: 3549 Mavis Road Mississauga L5C 1T7 Ontario Canada Year founded: 2006 Annual revenues 2007: $0 2008: $0 2009: $0 Type of technologies Drystill is a Canadian developer and supplier of chemical separation technology. The company has developed a ground-breaking process - perhaps the only economical one at present - for refining cellulosic and corn ethanol from weak beers in the 3-8 wt% ethanol range. This is a strategic breakthrough for the Biofuel industry that will lead to a paradigm shift in the way ethanol is produced in the future. At the heart of Drystill's technology is a proprietary, novel, apparatus called a Stripper/ Absorption Module ("SAM") - the first of its kind in the World. This key technology enables Drystill to apply advanced, processing techniques, such as: simultaneous fermentation and extraction ("SFE"); low temperature, vacuum evaporation; and multiple-effect distillation ("MED") of beers. The benefits of Drystill's technology to the Biofuel industry are significant, reducing both operating and capital costs. For example: c& SFE allows practical, continuous fermentation, using weak beers. Production is therefore faster (residence time is reduced by 85%), yeast is potentially less stressed and less prone to infection, and more productive. At the same time, consumption of yeast is lowered. c& The beer column is replaced by a MED device that does not suffer from fouling at high temperatures. c& Consumption of energy during refining is reduced be 50% or more, e.g. to below 10,000 BTU/gal for an 8 wt% ethanol beer. Hypothetically, if all the plants in North America were using Drystill's technology, more than $2 billion p.a. in energy alone would be saved, or recovered by selling the surplus. c& Capital expenditure is reduced by using smaller fermentation tanks (only 10% of size), cooling towers and steam plants, while beer columns and molecular sieves are replaced by less expensive and more efficient alternative equipment. In addition to the economic and technical benefits above, the environmental benefits are also very positive. Not only is energy consumption reduced substantially, but also the carbon footprint and water consumption. CO2 emissions are also reduced. Simultaneous fermentation & extraction Low temperature, vacuum evaporation Multiple-effect distillation Absorption/desorption Pervaporation/vapour permeation Solids handling Type of fuel produced Ethanol, butanol, other 3 top milestones 2008-9 Development of SFE technology Provisional patenting of unique Stripper/Absorption Module ("SAM") the key enabler of SFE and MED (see #5) Establishment of relationships with seven large ethanol plant designers and owners 3 major milestone goals for 2010-11 Attract a major investor Construct a pilot/demonstration plant Conclude a contract to install technology in a new plant, or retrofit an existing plant. Business model Licensing, component supply Competitive edges(s) Continuous ethanol extraction and fermentation Faster processing with low residence times Healthier & less stressful environment for yeast, leading to increased yield Reduced refining energy consumption by 50% or more Reduced capital expenditure Smaller carbon footprint Stage Pilot/demo Website URL www.drystill.ca Royal DSM Based in: Het Overloon 1 6411 TE Heerlen THE NETHERLANDS Year Founded: 1902 Annual Revenues: 2007: 8,757 million EUR (approx. 12,000 million USD) 2008: 9,297 million EUR (approx. 13,600 million USD) 2009 Jan-Jun: 3,791 million EUR (approx. 5,000 million USD) Due to the current macro-economic situation, DSM does not give a revenue outlook for 2009. Technology: White (industrial) biotechnology: Advanced micro-organisms, including microbial biocatalysts and an ethanologen capable of co-fermenting C5 and C6 sugars; Enzymatic hydrolysis, e.g. using cellulases and hemicellulases; Fermentation to biogas, biofuels and biobased chemicals, e.g. for the production of cellulosic ethanol, succinic acid, citric acid, vitamins, and antibiotic intermediates. Fuel type: Enzymes, advanced ethanol yeast and advanced processing technologies for cellulosic ethanol Major investors DSM is a publicly listed company at the NYSE Euronext Stock Exchange in Amsterdam, The Netherlands (ticker symbol DSM KON). 3 top milestones for 2008-09 2008: DSM has received a 7.4 M USD grant from the US Department of Energy for a drastic reduction of the cost price of enzymes for the hydrolysis of lignocellulosic biomass. DSM conducts this project in collaboration with its partners Abengoa Bioenergy, the Los Alamos National Laboratory, and the Sandia National Laboratory. 2009: DSM has acquired Biopract, which has developed the Methaplus"! enzyme series for the improvement of agricultural and industrial biogas production. Biopract is integrated into DSMs biogas service concept for optimizing the biotechnology of biogas plants. Based on a thorough analysis of the production process, DSM offers biogas plants tailor-made advice and a product mix to improve the performance of the plant. 2009: as a partner in the KACELLE consortium led by DONG Energy, DSM received a 1.1 M EUR grant from the European Commission (Framework Program 7) for the development of advanced ethanol yeast. This yeast has the potential to improve the economic viability of a wheat straw based biorefinery. 3 major milestone goals for 2010-11 Making cellulosic ethanol a commercial reality: Finalize development of a cost effective cellulases cocktail for the industrial scale hydrolysis of pretreated lignocellulosic biomass. Finalize development and start commercialization of advanced ethanol yeast for the industrial scale production of cellulosic ethanol from C5 and C6 sugars obtained from lignocellulosic biomass. Integrating and optimizing these technologies into an advanced biorefinery using agricultural residue streams such as wheat straw and corn stover for the production of cellulosic ethanol. Business model: Co-owner and operator of plants for the commercial demonstration of on-site production of lignocellulosic enzymes and advanced ethanol yeast, and licensing out of the hence developed technologies. Fuel cost: Not applicable. Competitive edge: DSM, the global Life Sciences and Materials Sciences company: has over 100 years of experience in enzymes and yeast development and production; is currently one of the top industrial biotechnology companies with over 2 billion USD of sales coming from industrial biotechnology based products; has all disciplines which are required to cost effectively produce cellulosic ethanol via the biochemical pathway in house; has an advanced research & development infrastructure for improvement of microorganisms for the production of enzymes, cellulosic ethanol and biobased chemicals; has developed an alternative cellulases enzymes system capable of further lowering the contribution of enzymes to biofuels total cost, going beyond the current state of the art; has an extensive manufacturing infrastructure for pilot and commercial production of enzymes and yeast; targets on-site production of enzymes and advanced ethanol yeast following the principle that only through integration and joint optimization with a biorefinery partner cost effective production of cellulosic ethanol can be achieved; is an important supplier of ingredients to the food and feed markets and is an innovative player in the field of performance materials, and is hence well positioned to provide innovative solutions for the valorization of biorefinery side streams, including proteins and lignin; is altogether a truly differentiated provider of a full package of biobased solutions for the cellulosic ethanol market. Alliances and Partnerships: DSM has set up multiple joint technology development partnerships in the field of cellulosic ethanol, similar to its current partnership with Roquette (France) on succinic acid. These partnerships may grow out into commercial demonstration plant partnerships and/or licensing-out partnerships. Development stage DSM produces enzymes and yeast for applications outside biofuels on a commercial basis. DSM runs pilot production of cost effective enzymes and advanced ethanol yeast for biofuel applications. Website:  HYPERLINK "http://www.dsm.com Dyadic" www.dsm.com  Dyadic Based in: Florida Business: Dyadic International develops applications for the bioenergy, industrial enzyme and pharmaceutical industries. Model: Licensor Past milestones: Dyadic filed an SEC 8-K form confirming that the company has received the final installment in $10 million in upfront payments from Codexis for a license to utilize "the use of Dyadic's C1 expression system for large-scale production of enzymes in certain fields including biofuels and chemical and pharmaceutical intermediate production." In 2009, received a generally recognized as safe ("GRAS") , notice from the FDA for cellulase enzyme preparation derived from a genetically modified strain of the company's proprietary C1 organism. The company said that it will immediately offer for sale a new liquid enzyme product produced from its C1 technology platform called, "CeluStar CL," for use in the production of wine, beer and fruit juices, and identify co-development and licensing opportunities for the future production of additional C1-derived GRAS products. Dyadic International develops applications for the bioenergy, industrial enzyme and pharmaceutical industries. Future milestones: Improving and leveraging technologies for use in such markets as cellulosic ethanol, industrial enzymes and pharmaceuticals and seeking mutually beneficial collaborations with leaders in such industries." Dynamic Fuels Based in: Louisiana Business: Dynamic Fuels is a 50/50 venture between Syntroleum and Tyson Foods.Develops process for converting low value and waste fatty acid/glyceride streams (from spent vegetable oils used in food processing to palm oil fatty acid distillate) into high quality hydrocarbon fuels (diesel, jet fuel, naphtha, and LPG). Model: 50/50 venture between Syntroleum and Tyson Foods. Dynamic Fuels business model is own and operate bio-refineries based on Syntroleums Bio-Synfining process. Past milestones: Dynamic Fuels has spent all of the past year staffing up and building a 75 million gal/yr plant in Geismar, LA (near Baton Rouge). This will be the first second generation biofuels plant in the U.S.--converting non-food biofeeds into drop-in hydrocarbon fuels. Future milestones: Commercial production is scheduled to begin during first quarter of 2010. URL: HYPERLINK "http://www.dynamicfuelsllc.com/"www.dynamicfuelsllc.com EdeniQ Based in: California( Business: EdeniQ supplies technology to the global biofuels industry that dramatically increases yields from today s corn and sugarcane ethanol plants and ultimately enables the capital-efficient migration of these so-called  legacy producers to full, non-food, cellulosic production. EdeniQ employs proprietary biological and mechanical processes that include low glycerol yeasts, SSF, proprietary enzymes, and proprietary comminution and desiccation devices. EdeniQ is primarily focused on cost-effectively converting cellulosic biomass into affordable C5 and C6 sugars that can then be processed into a wide variety of biofuels and biochemicals. The company is pursuing technologies to convert C5 and C6 sugars into heavier fuels including jet fuel. Model: Licensor. Past milestones: 1. Commercialized yield enhancement technologies in the U.S, and Brazil( 2. Advanced mechanical pre-treatment technology( 3. Advanced SSF/enzyme technology Future milestones: 1. Dramatically grow market penetration of our corn and sugarcane yield enhancement products: Corn3 and Eden3( 2. Build the demo for our CCM (Corn to -Cellulose Migration) solution.( 3. Have SSF and enzymatic technologies ready for commercialization. Metrics: Targeting $1.50 fuel cost without subsidies. Corn3 increases ethanol yields from corn by over 10%. Eden3 increases ethanol yields from sugarcane by over 4%. EdeniQ quotable quotes: Capital efficient, low-cost, and fast-to-market. The cost of migrating legacy producers to cellulosic production is about half the cost of building green field cellulosic plants and can be done in about half the time. In a capital constrained global economy we are committed to leveraging the billions of dollars already deployed in First generation production. ElectroSep Based in: PO Box 985, Corvallis, OREGON 97339 Year Founded: 1997 Annual Revenues: Small private engineering company presently operating in research and development mode. Revenues for 2010 are projected at $500,000 Technology: A patented electrolytic membrane separation technology combined with a novel mild pretreatment process that provides extraction and recovery of chemicals for production of cellulosic ethanol and butanol from wood and norwood materials. The value added coproducts exhibited in several pilot tests and the high sugar yields data obtained in preliminary lab tests performed by Electrosep and Oregon State University professor M. H. Penner showed that the Electrosep process may possibly produce nonwood cellulosic ethanol at commercially viable costs, i.e. approximately $1.15 per gallon of ethanol. Please refer to ATTACHED brief description of Electroseps Mild Pretreatment Breakthrough on Cellulosic Ethanol production. Fuel type: The new Electrosep process can be used for production of cellulosic ethanol and butanol from wood and nonwood raw materials. Major investors: The company is privately owned. The research and pilot development work was mainly funded with private investment. Some pilot projects were funded by a major energy corporation in Canada and a large company in Switzerland. The original electrolytic chemical extraction technology was pilot tested at a pulp and paper mill in the state of Washington. The US Dept. of Energy (Golden Office) funded part of the $2.5 million cost of the pilot project. Past milestones (08-09): a. Performed pilot tests on electrolytic caustic soda recovery, generation of hydrogen, and extraction of lignin from black liquors generated at several softwood pulp and paper mills in Canada. This pilot operation was part of an ongoing project being performed by Electrosep and a major multi-billion dollar energy corporation in Canada. These tests provided energy consumption data for softwood liquor treatment on a continuous 24-hour basis. The data showed that caustic soda and coproducts may possibly be produced at commercially viable costs. b. Performed bench scale testing special mild pretreatment of softwood and corn stalk materials in reactor followed by enzymatic saccharification for glucose production using conventional types of enzymes The enzymatic hydrolysis work was performed by Oregon State University professor M. H. Penner, PhD. c. Formed a joint working relationship with OSU professor M. H. Penner to jointly perform bench scale tests on sugar production using Electrosep pretreated wood and nonwood cellulosic materials. Electrosep and OSU have applied and will continue to apply for grants in pursuit of funds for research during year 2010 and beyond. 3 major milestone goals (2010-11) a. Test the electrolytic process and determine projected years of durability for various types of electrodes and membranes, i.e. DuPont Nafion perfluorinated membrane and other possible suppliers. b. Bench tests to determine glucose and xylose yields using maximum glucan and xylan concentrations in hydrolysates produced from EL pretreated cellulosic materials. Tests should include various types of enzymes and genetically engineered microbes to determine optimum yields at minimum cost for cellulosic ethanol and butanol production using EL pretreated materials. c. Pilot scale testing the cellulosic ethanol production process from nonwood and wood raw materials Business model: Engineering design and licensing the technology Fuel cost: Preliminary estimates of net fuel cost are approximately $0.45 per gallon of ethanol for norwood and $0.96 oer gallon of ethanol for wood. The overall production cost is estimated at $1.15 per gallon of ethanol for nonwood cellulosic ethanol and approximately $1.85 per gallon of ethanol for wood. Competitive edge(s): (e.g. Distribution, economies of scale, low-cost, yield, etc). Yields and coproducts provide low cost cellulosic biofuels Alliances and Partnerships: Research or production partnerships and alliances are acceptable Development stage The electrolytic chemical recovery process is presently at pilot stage. The hydrolysis process may be pilot tested soon after bench scale optimization tests are completed. Website URL www.electrosepinc.com Enerkem Inc. Based in: 615 Ren-Lvesque Blvd West, Suite 820, Montral, QC (Head Office) Year Founded 2000 Business: The Company uses a proprietary thermo-chemical technology (green gasification and catalytic conversion) to convert heterogeneous materials into ethanol. R&D is underway to produce Synthetic gasoline (syngas), Synthetic diesel, and Dimethyl Ether (DME). The Company is majority owned by clean-technology investment pioneers and institutional funds, including Rho Ventures, Braemar Energy Ventures and BDR Capital. The Company was founded in 2001. Type of technology(s) Thermo-chemical technology (green gasification and catalytic conversion) Type(s) of fuel produced (e.g. ethanol, green gasoline, biodiesel, etc) Ethanol. R&D underway to produce Synthetic gasoline (syngas), Synthetic diesel, and Dimethyl Ether (DME). Can also produce green chemicals, such as methanol, acetic acid, and acetates Major investors. Majority owned by clean-technology investment pioneers and institutional funds, including Rho Ventures, Braemar Energy Ventures and BDR Capital. 3 top milestones for 2008-09. 1. Started operating its commercial demonstration plant in 2009. It is expected to produce methanol by the end of 2009 and ethanol shortly after. The plant will produce 1.3 million gallons of ethanol from used electricity poles (treated wood). 2. Signed a 25-year supply agreement with the City of Edmonton (Alberta, Canada) to build and operate a municipal solid waste-to-biofuels project. The project received the necessary environmental permitting, and is ready to start construction by the end of 2009. 3. Announced its first biofuels project for the United States (Mississippi), along with its agreement with the Three Rivers Solid Waste Management Authority of Mississippi (TRSWMA) for the supply of municipal solid waste as feedstock. 3 major milestone goals for 2010-11. 1. Production of methanol and second generation ethanol will begin at its Edmonton municipal solid waste-to-biofuels production facility. The plant will produce 10 million gallons per year. 2. Construction of its waste-to-biofuels facility in Pontotoc, Mississippi will commence. The plant will produce 20 million gallons per year from sorted municipal solid waste and wood residues. 3. Additional projects will be launched, as Enerkem is currently developing these plans in North America. Business model: Owner/operator Fuel cost: N/A Competitive edge: Proven thermo-chemical technology, through more than 3,600 hours of rigorous piloting and testing, since 2003. Pioneered technology is feedstock flexible, allowing the Company to use sorted municipal solid waste as well as agricultural and forest residues; therefore, can develop projects in both rural and urban centers. One plant is capable of converting more than one type of feedstock. Technology is designed to employ low-value, non-homogenous biomass feedstock, such as municipal solid waste (MSW). This gives Enerkem a strong competitive advantage, as its feedstock is a source of revenue (receives waste disposal fee). Efficient modular plant model with scalable units of 10 M gallons/year of biofuels. Standardized plant design that Enerkem can easily replicate. Partnerships with cities and counties through long-term supply agreements. Multi-product technology platform, making it possible for Enerkem to produce advanced transportation fuels, green chemicals and renewable electricity. The Company therefore has the capability to develop a wide range of projects based on market conditions, from biorefineries to renewable electricity plants. Strong in-house engineering and equipment procurement expertise. Environmentally-friendly process and plant model: Low energy requirement, as the gazifier is auto-thermal and the chemical reactions produce most of the energy and heat needed; Water is re-used in a closed-circuit, and the process is often a net producer of water; Facilities are compact, decentralized and located near the feedstock supply; An alternative to landfilling and complementary to recycling. Distribution, research, marketing or production partnerships or alliances. Partnership with the City of Edmonton. Signed a 25 year agreement for the supply of sorted municipal solid waste to be used as feedstock. The Edmonton biofuels plant will be situated at the Citys leading Edmonton Waste Management Center (EWMC). Partnership with the Three Rivers Solid Waste Management Authority of Mississippi (TRSWMA): Signed a Memorandum of Intent for the supply of189,000 tons of unsorted municipal solid waste per year, for use as feedstock. The facility will be located at the Three Rivers landfill site in Pontotoc (Mississippi, US). R&D Collaborations with: University of Sherbrooke, LeHigh University, Mississippi State University and Alberta Energy Research Institute. Off-take agreements with fuels blenders, refiners, distributors and chemical companies. Development stage: Commercial deployment (full-scale plants): Edmonton (Alberta, Canada) (fully permitted, construction to start end of 2009) Pontotoc (Mississippi, US) (construction expected to start in 2010) Enerkem has rigorously gone through the entire path to commercialization, from: lab to pilot to commercial demonstration to commercial. Over 20 types of feedstock have been tested, during more than 3,600 hours of operations at its pilot plant, since 2003. Its commercial demonstration plant is producing a stable and high quality conditioned syngas, which will be the chemical feedstock for the production of methanol and ethanol in the upcoming months. Metrics: Enerkem has an efficient modular plant model with scalable units of 10 M gallons/year of biofuels from waste and residues. Its standardized plant design can easily be replicated. The 10 M gallons of ethanol can reduce CO2 emissions by 240000 tonnes per year. Enerkems thermo-chemical technology has been proven through more than 3,600 hours of rigorous piloting and testing, since 2003. The Company has signed a 25 year agreement with the City of Edmonton for the supply of 100,000 tonnes of sorted municipal solid waste to be used as feedstock. The Edmonton biofuels plant will be situated at the Citys leading Edmonton Waste Managed Center (EWMC). Enerkem has also signed a Memorandum of Intent for the supply of189,000 tons of unsorted municipal solid waste per year, for use as feedstock, with the Three Rivers Solid Waste Management Authority of Mississippi (TRSWMA), for its Pontotoc (Mississippi, US) plant. Enerkem quotable quotes: Enerkem is proud to have gone through the entire rigorous path to commercialization, moving from: lab to pilot to commercial demonstration to commercial. This has allowed Enerkem to ensure a smoother transition to commercialization and an optimization of its process. The Companys technology is feedstock flexible, allowing it to use sorted municipal solid waste as well as agricultural and forest residues. Therefore, it can develop projects in both rural and urban centers. One of our plants is capable of converting more than one type of feedstock. This gives Enerkem a strong competitive advantage, as its feedstock is a source of revenue (receives waste disposal fee).The technology is also a multi-product technology platform, which makes it possible for Enerkem to produce advanced transportation fuels, green chemicals and renewable electricity- a wide range of projects based on market conditions. Our process is environmentally-friendly, as the water is re-used in a closed-circuit and the process is often a net producer of water; our facilities are compact, decentralized and located near the feedstock supply; and, our use of waste provides an alternative to landfilling and is complementary to recycling. Enerkems plant model also requires low energy, as the gasifier is auto-thermal and the chemical reactions produce most of the energy and heat needed Enhanced Biofuels Based in: Texas Business: Non-caustic esterification or transesterification Model: Licensing Past milestones: Secure commitments from strategicv partners, investors and customers Future milestones: Formalize commitments, build semi-works, build com[pany infrastructure. Metrics: Enhanced Biofuels is a Houston-based alternative diesel technology company that has developed the HS Reactor Systemtm. This proprietary system is able to process a multitude of traditional and less expensive non-food feedstock with up to 100% FFA into advanced biodiesel. No other technology can effectively match this performance. As a full train retrofit or front end pre-treatment, the HS Reactor Systemtm can be cost-effectively integrated into existing biodiesel, ethanol, pulp & paper, and edible oils operations to leverage existing infrastructure, and increase production flexibility and profitability. Enhanced Biofuels has proven the system through its pilot operations and now stands ready to market the technology through its first commercial installation. Enhanced Biofuels will execute a technology licensing and royalty business model whereby the company will provide its technology to fuel producers and feedstock suppliers. Fulcrum Bioenergy Based in: 4900 Hopyard Road, Suite 220, Pleasanton, CA 94588 Year Founded: 2007 Annual revenues 2009 Projected: $0; 2008: $0; 2007: $0, Type of technology Fulcrum utilizes new emerging technologies to convert post-recycled municipal solid waste (MSW) feedstock to cellulosic ethanol. Fulcrum is deploying new technologies in a clean, efficient and proven two-step thermochemical process. In the first step, MSW received from feedstock suppliers under long-term contracts, will be processed through a down-draft partial oxidation gasifier followed by a plasma arc. This combination provides a highly efficient and economic method of creating a synthesis gas, or syngas, consisting mainly of hydrogen, carbon monoxide and carbon dioxide. In the second step, the syngas will be converted to ethanol through an alcohol synthesis process developed by Fulcrum using a new, proprietary catalyst technology. Type(s) of fuel Cellulosic ethanol from municipal solid waste; conversion occurs post-recycling and composting programs. Major investors. Fulcrum is privately held and financed by US Renewables Group, LLC, which manages a portfolio of renewable power and clean-fuel assets, and Rustic Canyon Partners, a large venture capital firm based in Southern California. 3 top milestones for 2008-09. Fulcrum successfully tested both of its new, innovative technologies which included: A two-phase gasification process that converts MSW to syngas; and An alcohol synthesis process that converts syngas to 100% alcohol. Significantly advanced the development of Fulcrums first large-scale plant, the Sierra BioFuels Plant, a first-of-its-kind facility designed to convert 90,000 tons per year of post-recycled MSW into 10.5 million gallons of cellulosic ethanol: Acquired property for the Plant located 20 miles east of Reno, NV; Established site infrastructure; Completed full front-end engineering design work; Received permits to begin construction; Secured fixed price, long-term feedstock contracts; and Positioned the Plant to begin construction by early 2010. Secured several long-term, fixed cost feedstock contracts with large waste service companies across the U.S. These contracts will provide Fulcrum with enough feedstock to generate one billion gallons of ethanol per year, displacing 14 million barrels of oil annually. 3 major milestone goals for 2010-11. Complete construction and commence commercial operations of the Sierra BioFuels Plant positioning Fulcrum as the leader in the next generation of advanced biofuels. Begin construction of the next phase of larger waste-to-ethanol facilities and further develop multiple plants across the U.S. Complete evaluation and testing of additional emerging technologies that can efficiently convert MSW to ethanol in a clean, sustainable manner and begin testing of 2nd generation gasification and alcohol synthesis systems. Business model: Developer/Owner/Operator Fuel cost: By recycling heat and energy within the MSW-to-ethanol plant, Fulcrum is able to reduce its cost of production to less than $1.00 per gallon. This represents a dramatic reduction in the cost of production when compared to both conventional ethanol production as well as other cellulosic ethanol production models using agricultural and wood-waste feedstocks. Competitive edge: Fulcrum is leading the next generation of clean, sustainable alternative transportation fuels advanced biofuels. Our competitive advantages include: Emerging Technology: Fulcrums approach will integrate new, innovative technology that has been proven on a non-commercial scale to efficiently convert post-recycled MSW to cellulosic ethanol. We worked closely with outside engineering firms to evaluate numerous technologies for processing various waste streams and have secured licenses and intellectual property rights with three different technology providers, giving Fulcrum the ability to deploy the right best-in-class technology based on the feedstock, size of plant and desired transportation fuel. Strong First Mover Competitive Advantage: Fulcrum has secured long-term, fixed price, feedstock contracts to lock up access to key waste streams across the U.S. With these contracts, we have secured access to enough feedstock to generate one billion gallons of cellulosic ethanol per year. These fixed, long-term contracts provide Fulcrum with access to the lowest cost feedstock and secure key locations in the waste shed. Additionally, Fulcrum has identified what it believes are the most commercially feasible waste-to-ethanol technologies. Profound Environmental and Social Benefits: Fulcrums innovative approach efficiently transforms our everyday trash into a reliable domestic fuel source. Complementing and enhancing recycling efforts, Fulcrums process of producing ethanol provides profound environmental and social benefits. Our projects will create a reliable domestic source of renewable fuels from non-agricultural feedstock, reducing greenhouse gas emissions by more than 75% compared to the production of traditional refined gasoline, helping to alleviate our Nations dependence on foreign oil, creating new green jobs and relieving pressure on existing and future landfills. Low-Cost Producer: Post-recycled MSW is an attractive feedstock for conversion to renewable transportation fuels with large volumes existing near dense population centers and in areas of strong transportation fuel demand. With fixed price contracts, Fulcrums cost of production will be 50% lower than conventional agricultural-based methods. Sierra BioFuels Fulcrums First of a Planned Fleet of Larger Projects Across the Nation: Fulcrum is scheduled to begin construction in early 2010 on its first large-scale project, the Sierra BioFuels Plant, outside of Reno, Nevada using new technologies in an innovative, clean, efficient, and proven process. Utilizing approximately 90,000 tons per year of post-recycled MSW waste from a city with the population of 165,000 the plant is designed to produce 10.5 million gallons of cellulosic ethanol annually. Distribution, research, marketing or production partnerships or alliances. Sierra BioFuels has entered into a letter of intent with a nationally respected firm for the marketing and transportation of its ethanol product. Development stage: Sierra BioFuels is in late stage development with front-end engineering and design work complete. Engineering, procurement and construction is anticipated to commence early 2010.The Sierra BioFuels facility will deploy two new, innovative technologies that, when combined with existing commercial systems, will be one of the Nations first facilities to convert post-recycled MSW feedstock to cellulosic ethanol: a down-draft partial oxidation gasifier in combination with a plasma arc system; and an alcohol synthesis process integrating a proprietary catalyst. The down-draft partial oxidation gasifier has undergone extensive pilot and demonstration plant testing, while the plasma arc system has been operating commercially at various locations. Fulcrum has confirmed the economics and efficiencies of the combined gasifier and plasma arc through a number of tests at a demonstration facility. The catalyst technology has completed pilot plant testing. The alcohol synthesis process is currently operating at a demonstration unit, which converts the syngas to 100% ethanol. Website HYPERLINK "http://www.fulcrum-bioenergy.com/"www.fulcrum-bioenergy.com Genencor Based in: 925 Page Mill Rd, Palo Alto, CA 94304 Year Founded: 1990 Annual Revenues: Genencor Division is one of three Divisions of Danisco. From recent quarterly reports, Global Danisco revenue outlook for fiscal 2009/10 is around DKK 13.5 billion (roughly $2.5 Billion US). Genencor revenue in 2008/09 (ending in April 09) was DKK 4,065 Billion (roughly $770 Million US). Danisco is making major investments on several fronts to be at the forefront of renewable biofuels and biochemicals. Technology: Industrial Enzymes Cellulosic Enzymes Enzyme engineering and production Synthetic Biology Fermentation Processing Industrial Biotechnology for Renewable Biofuels and Biochemicals Fuel type: Industrial Enzymes: Enzymes for 1st Generation Bioethanol (i.e., Enzymes for Starch Hydrolysis) Enzymes for Biomass Hydrolysis, (i.e., Cellulosic Ethanol) Biochemicals: C5 BioIsoprene"! platform for use in synthetic rubber; adhesives and specialty elastomer applications BioFuels: C5 BioIsoprene"! platform for use in the production of branched chain hydrocarbons, C10 gasoline; C15 biodiesel and jet fuel blend stocks. Major investors: Danisco is a public company listed on the Danish Stock Exchange, with many institutional investors. Danisco and DuPont have recently established a joint venture (DuPont Danisco Cellulosic Ethanol JV) which was one of last years Biofuels Digest Top 10 Hottest Companies. Past milestones (08-09): First company to launch a commercial enzyme for biomass hydrolysis - Accellerase 1000. We launched an improved commercial enzyme product (Accellerase 1500) in Feb 2009, as well as three "accessory enzymes" for process development. A multi-million dollar DOE award for Enhancing Cellulase Commercial Performance for the Lignocellulosic Biomass Industry was announced in Feb 2008. Began bulk shipment of Accellerase 1500 enzymes to cellulosic ethanol pilot and demo plants. Announced an R&D collaboration with The Goodyear Tire and Rubber Company to establish a bio-based process to produce isoprene (BioIsoprene"!) in September 2008. The first shipment of test quantities of BioIsoprene"! product to Goodyear was announced in March 2009. Copenhagen Climate Summit, December 2009: Cars used by dignitaries at this critical summit will prominently feature Genencor technology. The cars will be powered by the first cellulosic ethanol produced by Inbicon in their Kalundborg, Denmark plant. Accellerase enzymes are used in their process. 3 major milestone goals (2010-11) Continuing launch of high performance enzyme products that dramatically lower cost in use to enable the cellulosic biofuels industry. Launching several new enzymes to reduce chemical costs, water and energy use in the production of 1st generation biofuels. BioIsoprene"! C5 Platform: Genencor builds relationships to enable further pilot and commercial development of BioIsoprene"! and BioIsoFuels"!, branched chain hydrocarbon advanced Biofuels. Business model: Merchant enzyme supplier to ethanol/Biofuel industry Integrated solutions provider in cellulosic Ethanol industry through DDCE JV. Developer/ Owner / Operator of BioIsoprene"! C5 platform for biochemicals and biofuels. Fuel cost: We believe that BioIsoFuels"! will be cost competitive with other advanced biofuels. Gas phase recovery of BioIsoprene"! from fermentation of biomass feedstocks enables a cost advantaged process. Competitive edge: Genencor delivers now to accelerate biorefinery commercial success! Be it starch ethanol, cellulosic ethanol, other biofuels or even renewable biochemicals, Genencor is one of the few industrial biotech companies that offers everything from discovery to delivery of new enzymes and products. We have a strong IP portfolio, global production capability and economies of scale that few other companies can challenge. Our innovation continues with world class R&D efforts to deliver dislocating products at cost structures that are relevant for the biofuels and renewable biochemicals markets. Many people have good stories in this area, but Genencor is delivering today. Alliances and Partnerships: Renewable biochemical development (BioIsoprene"!) Research collaboration with the Goodyear Tire and Rubber Company. DDCE Joint Venture between Danisco and DuPont Multi-million dollar DOE Award announced in 2008 for Enhancing Cellulase Commercial Performance for the Lignocellulosic Biomass Industry. Development stage Our Starch to Ethanol Enzymes are of course at commercial scale. We know this business well, but continue to launch innovative new products to support this industry as it continues to grow. Our Cellulosic Enzymes (Accellerase) are also produced at commercial scale. We are currently supplying enzymes at bulk scale to cellulosic ethanol pilot and demo plants. Our BioIsopreneTM efforts are at a pre-pilot stage with commercial development expected in a 2013-14 time frame targeting tire; adhesive and specialty elastomer markets. Website: www.danisco.com www.genencor.com www.accellerase.com GeoSynFuels 1. Company name GeoSynFuels, LLC Based in:: 14818W. 6th Ave, Suite A1, Golden, CO 80401 Year Founded: 2006 Annual Revenues:: None Technology: Simultaneous Saccharification and Solid-State Fermentation SSSSF Fuel type: Ethanol and potential for other advancd biofuels such asbiobutanol Major investors: Private equity- Large net worth individuals. Past milestones (08-09): 1. Complete engineering design for pilot plant 2. Develop effective 5-carbon fermentation microbe and process 3.Establishin-house proprietary pretreatmentcapabilities for large scale testing. 3 major milestone goals (2010-11) 1. Build and operate pilot facility. 2. Commence construction of first commercial plant. 3. Develop business opportunities outside USA Business model: Build, own and operate. Fuel cost: Costs are highly dependant on the feedstockunder considerration and the particulars of the process. GeoSynFuels has several processing routes that range from treating beetle killed pineforboth hemicellulose and cellulose conversion and fermentation to treating waste fiber (MSW, waste paper, etc) whcih requires no pretreatment. The beetle kill process has a projected price of $1.25 per gallon while the waste fiber process will be less than $1. Competitive edge:( Much of GSF's competitive advantage comes from the simplicity and scalability of the process but additional advantages come from a strategy of rapid scaleup, recognition of the existing commercialization barriers and strategic industrial partnerships. We project capital costs 5 -10X lower than competing processes and operating costs in the $1 per gallon range. These are made possible by: Focus on low cost feedstocks; Co-location benefits High yields; Low energy usage; Low water usage; Highly scalable. Alliances and Partnerships:( GSF hascommercial alliance with a largepulp and paper producer- we have completed a feasibility study for the processing of waste fiber at one of their sites. GSF has an alliance with Novozymes who provide our enzymes. We have obtained considerableassistance from this group and have tested many of their beta versions in our process. GSF has adevelopment agreement with Clean Tech Biofuels to test their MSW pretreatment materias in our process. GSF has formed a JV with the Donald Danforth Plant Science Centercalled Agrius BioForms LLC. This group is focused on the development of seed based enzymes and other industrial proteins. GSF has several MTA's in place from groups like NREL, Forest Products Lab, Ceres etc...( Development stage( GeoSynFuels is currently a development company focused on the construction of our continuous pilot plant. We have applied for a DOE grant to fund this development but have a contingency plan for Jan 1 2010 should we not be awarded a grant. Website: HYPERLINK "http://www.geosynfuels.com/"www.geosynfuels.com Glycos Bio Based in: 711 Leverkuhn, Houston TX 77007 Year Founded: - 2007 Annual Revenues: - Confidential Technology: GlycosBio uniquely discovered a number of microorganisms that biologically make green chemical intermediates from a variety of low value carbon feedstocks, like glycerol and free fatty acids. By not following the typical sugars based fermentation research, GlycosBio and biorefinery partners are protected from the commodity risk and single feedstock business models that have historically plagued the biofuels and alternative energy industries. Fuel type: GlycosBio has engineered a series of metabolic pathways that produce nearly a dozen chemical intermediaries. GlycosBios microorganisms produce diols, acids, and fuel alcohols ethanol and butanol. Major investors Draper Fisher Jurvetson and DFJ Mercury. 3 top milestones for 2008-09 250 L Pilot facility implemented 3 major milestone goals for 2010-11 Commercial scale facilities online Business model: - GlycosBio creates microbes and process technologies that are licensed to joint venture biorefineries. Partnership opportunities exist for chemical companies, palm oil companies, biorefiners, biofuel producers ethanol and biodiesel plants. The partners then use the microbes to biologically produce higher value chemicals from traditionally low value carbon co-product streams. Fuel cost: - Partner biorefineries that choose to license GlycosBios microbial strains to convert feedstocks into higher value chemicals can increase product values between 10-15 times the original value of the carbon feedstock source. Competitive edge: - GlycosBios proprietary technology provides an alternative approach to traditional corn or sugar-based biofuel and chemical production. By creating microbial strains that can convert low-value glycerin, or non-sugar based feedstocks, into higher value chemicals, GlycosBio can help partner biorefineries create greater yields as well as an energy balance that solves the food-verse-fuel debate. Through this business model, GlycosBios bioconversion technologies will enable the rapid implementation of a biorefinery leveraging existing infrastructure to increase plant product diversity and business profits. The additional revenue and profitability generated by diversifying into higher value chemicals creates a financial sustainability the industry has long sought. Alliances and Partnerships: - NA Development stage - GlycosBios genetically engineered microbial strains are available today to partner biorefineries. Website URL HYPERLINK "http://www.glycosbio.com"www.glycosbio.com GreenShift Corporation GreenShift develops and commercializes clean technologies designed to integrate into and leverage established production infrastructure and distribution channels to address the financial and environmental needs of its clients by decreasing raw material needs, facilitating co product reuse, and reducing the generation of wastes and emissions. GreenShift s founding mission is to build value by using its technologies to catalyze disruptive environmental gain. GreenShift believes that the first, best and most cost effective way to achieve this is to develop technology driven economic incentives that motivate large groups of people and companies to make incremental environmental contributions that are collectively very significant. GreenShift s plan to achieve this goal is based on the extraction, beneficiation and refining of biomass derived co products that create value added renewable energy production opportunities capable of shaving meaningful amounts of carbon and cost off of existing liquid fuel supply chains. Since 2004, GreenShift has invented, developed and commercialized potent new cleantech that enables GreenShift and its clients to  drill into the back end of first generation corn ethanol plants to tap into a new reserve of inedible crude corn oil with an estimated industry wide output of about 20 million barrels per year. This corn oil is a valuable second generation feedstock for use in the production of biodiesel and renewable diesel  advanced carbon neutral liquid fuels, thereby enhancing total fuel production from corn and increasing ethanol plant profits. GreenShift s patented and patent pending Corn Oil Extraction Technologies are widely considered to be the quickest and best path for margin improvement for first generation corn ethanol producers today. GreenShifts extraction technologies increase biofuel yields per bushel of corn by 7% while reducing the energy and greenhouse gas (GHG) intensity of corn ethanol production by more than 21% and 29%, respectively. These benefits correspond to increased ethanol producer income of about $0.12 per gallon of ethanol produced at current market prices, and can be realized for less than 10% of the capital cost of the host ethanol plant. No technologies have been developed for corn ethanol producers that begin to approach even a fraction of these results in the history of the ethanol industry. Over 20% of the U.S. ethanol industry is using GreenShift s patented and patent pending extraction technologies today. At full participation by the ethanol industry, GreenShift s commercially available technologies can give way to the disruptive gains that GreenShift was founded to achieve by sustainably producing globally meaningful quantities of new carbon neutral liquid fuels for distribution through existing supply chains and combustion in our nation's boilers, generators and engines; displacing more than 20 million barrels per year of crude oil; saving up to 10 trillion cubic feet per year of natural gas; eliminating tens of millions of metric tons per year of greenhouse gas emissions; and infusing up to a billion dollars per year of cash flow into the corn ethanol industry  the foundation of North America s renewable fuel production capability. GreenShift is focused today on supporting integration of its patented and patent pending corn oil extraction technologies into as much of the ethanol fleet as possible. GreenShift also maintains its strong commitment to continued innovation and has many additional patents pending for its  Backend Fractionation portfolio of strategically compatible cleantech designed to continue pressing the corn ethanol industry into increased sustainability and global competitiveness. Address: New York Year Founded :2004 Annual Revenues: 2009 about $5,000,000 (projected); 2008 $23,600,000; and, 2007 $14,700,000 Type of Technology(ies) BACKEND FRACTIONATION TECHNOLOGY PORTFOLIO Technology Function Status - Corn Oil Extraction Extraction of corn oil from ethanol co product  Commercially Available Transesterification- Integrated refining upgrade for corn oil extraction facilities  Commercially Available Cellulosic Oil"! Oleaginous microbes convert biomass into oil and protein  Pilot Stage Desiccation/Cavitation Conditions corn and qualified biomass for increased yields  Pilot Stage Biopolymer Extraction Extract and convert byproducts into bioplastics  Pilot Stage Photonic Fuels"! Reform exhaust carbon dioxide into natural gas and liquid fuels  Bench Stage Fuel Type: Corn Oil Extraction Produces inedible corn oil feedstock for conversion into biodiesel or renewable diesel Transesterification Biodiesel Cellulosic Oil"! Produces lipids for conversion into biodiesel or renewable diesel Desiccation/Cavitation Enhances Corn Oil Extraction and Cellulosic Oil"! yields for biodiesel or renewable diesel Photonic Fuels"! Methane (for use on site in lieu of fossil fuels) and liquid fuels (for sale off site) Major Investors YA Global Investments, L.P. 3 Top Milestones for 2008 09 A. Complete financing for construction of new facilities based on patented and patent pending corn oil extraction technologies. B. Form strategic partnerships to accelerate and amplify execution of go to market strategy for corn oil extraction technologies, and to enhance the development of pilot and bench stage technologies. C. Restructure $40 million in historical debt raised during 2004 2007 to develop and commercialize extraction and refining technologies. 3 Major Milestone Goals for 2010 11 A. Build value for GreenShift s clients and shareholders by building as many corn oil extraction facilities as possible, as quickly as possible, with a view towards achieving 100 million gallons per year of installed corn oil extraction capability within 5 years. B. Continue to improve upon patented and patent pending corn oil extraction and related technologies (i) to maximize yield, (ii) to decrease cost, energy and carbon, and (iii) to enhance the value proposition to GreenShift s clients and shareholders. C. Make a meaningful contribution to shifting the corn ethanol industry into increased economic and environmental sustainability by demonstrating the commercial viability of GreenShifts full Backend Fractionation technology portfolio in collaboration with strategic partners. Business Model: GreenShifts business model is based on Feedstock Ownership and Margin Protection. A sustainable mining business requires a cost effective and reliable source of ore; a sustainable petrochemical refinery requires a cost effective and reliable source of petroleum; and a sustainable biofuels business requires a cost effective and reliable source of feedstock. GreenShift uses its technologies to sustainably produce biomass derived products by targeting, extracting, acquiring and refining cost effective and reliable raw materials. GreenShift does not generally sell equipment based on its technologies, nor does it provide services based on its technologies, nor does it license its technologies in any conventional way. Instead, GreenShift licenses its patented and patent pending corn oil extraction technologies to corn ethanol producers in return for the right to purchase the extracted oil for the life of the use of the technology. GreenShift earns money by buying and selling or refining the extracted oil. The price paid for the oil corresponds to a substantial premium to the value of the oil to participating ethanol producers prior to extraction. At this rate, GreenShift retains about 20% of the value of the extracted oil. Fuel Cost (per gallon) The capital cost of corn oil extraction can range from $1.50 to as high as $3.00 per gallon of installed capacity, depending on the specific operating conditions of each host ethanol plant, and the desired oil yield and energy savings. Competitive Edge(s): GreenShifts primary competitive advantage is its use of its technology positioning to deliver powerful competitive advantages to the renewable fuels industry increased sustainability, reduced cost, reduced energy, and reduced carbon, all through the industrys existing production assets. A. For GreenShifts Ethanol Clients increased revenue and earnings; decreased commodity and financial risk; increased nutritional content of DDGS; enhanced energy balance with less carbon emissions; safe harbor from tight margin environments; strong cost advantage; and, increased sustainability and competitiveness. B. For GreenShifts Partner Biodiesel and Renewable Diesel Producers reliable large volume supply of previously unrecovered feedstock (versus no available feedstock); sustainable feedstock available at rates indexed to diesel fuel prices; safe harbor from tight margin environments; strong cost advantage; and, increased sustainability and competitiveness. For context, with a majority of plants adopting GreenShift s patented and patent pending corn oil extraction technologies, and with an estimated 11.5 billion gallons of ethanol produced, the ethanol industry could be saving about 100 million MMBtu per year while producing more than 2.8 million tons of inedible corn oil per year (over 736 million gallons). The result at current market prices is staggering: the ethanol industry could be producing an additional $0.12 per gallon of ethanol produced, or over $1.1 billion, in additional profit today by using GreenShifts patented and patent pending corn oil extraction technologies. Moreover, at 736 million gallons of extracted corn oil potential, backend corn oil could increase the output of the entire existing domestic production of biodiesel several fold. Distribution, Research, Marketing or Production Partnerships or Alliances. GreenShifts partnerships include relationships with ethanol, biodiesel and renewable diesel producers. GreenShift is collaborating with corporate partners relative to its efforts to improve on the value proposition of its corn oil extraction and Backend Fractionation technology portfolio. In addition, GreenShift has developed partnerships with a number of academic institutions relative to its ongoing technology development and commercialization efforts. Stage Corn Oil Extraction Technologies Commercial Website URL www.greenshift.com Joule Biotechnologies Based in: 83 Rogers Street, Cambridge, MA 02142 Year Founded: 2007 Annual Revenues: N/A Technology: Joule is pioneering a transformative technology that we believe supersedes existing and emergent cellulosic or algal biomass-derived fuel approaches by employing genetically engineered photosynthetic organisms that directly convert sunlight and waste CO2 to fuel and chemical molecules. Our proprietary Helioculture"! technology is being designed to produce liquid energy in the form of ethanol and diesel that will target the worldwide need for renewable, clean transportation fuels at a price expected to meet or beat market pricing. We also may create a whole range of petroleum-derived chemical products to be commercialized via partnerships with industry leaders. Fuel type: Ethanol and Diesel Major investors: Flagship Ventures Past milestones (08-09): Achieved significant progress in the development of Helioculture"! technology and a proprietary, genome engineering toolkit, and important progress Based in:ing the technical challenges of scalable reactor and large-scale process design. Achieved first long-term ethanol production in SolarConverter"! system, and first outdoor production. Achieved cellular production of diesel in the lab. 3 major milestone goals (2010-11) Continue gains in productivity and yield for Joule ethanol and Joule diesel liquid energy. Continue optimization of our SolarConverter systems. Commence pilot plant operations for Joule ethanol and diesel liquid energy. Business model: Options for Joule will range from direct sale of liquid energy and chemical products, to partnerships and joint ventures with existing market leaders and CO2 producers, to OEM and licensing arrangements enabled by the companys intellectual property platform and know-how. As a result, the strategy over the short-term will be to continue to drive the technology towards commercialization and let partnership discussions and access to capital dictate the best way to create shareholder value. Joule has the advantage of a team of seasoned professionals with proven experience creating significant shareholder value in multi-business unit models. Fuel cost: Estimated at the energy equivalent of less than $50 per barrel for diesel and less than $81 per barrel for ethanol. Competitive edge: Joule s Helioculture"! technology has a number of distinct advantages. Relative to fossil fuels or to biomass-derived methods, it has a Direct-to-Product"! process, thus eliminating costly middle steps such as fermentation, large-scale biomass removal or other down-stream refinement. In addition, Joules process has the capability of achieving up to 10X more efficient land use versus biomass-derived methods without the need for agricultural land or clean water. By eliminating raw material feedstock requirements, the technology also removes a costly component that can be subject to significant fluctuations in price and availability. The Helioculture"! technology is being designed to offer a high net energy yield, to be highly modular and scalable and to provide a technology platform capable of making multiple products. To date, Joule has demonstrated in the lab proof of principle on greater than 10 fuels and chemicals. Other advantages include: Highly-Scalable Production System The modular SolarConverterTM system is designed to optimize solar energy capture, CO2 delivery and mixing, organism cultivation and product separation, and is designed for easy connection in order to simplify installation and logistics. As a result, these systems are expected to be easily scalable and thus customizable to any desired size, based on land and CO2 availability. Strong Intellectual Property Position -- Joule has developed a broad based, multifaceted estate covering core technologies and products. Experienced Leadership -- Joules management team has a solid track record of creating significant shareholder value in IP-centric, multi-business unit models. Development stage Development Website:  HYPERLINK "http://www.joulebio.com" http://www.joulebio.com LanzaTech Based in: New Zealand( Business: Developer of a technology that converts CO2 from coal-fired power plants to Carbon monoxide gas is produced in high volumes by the steel industry. Industrial waste gases contain elevated concentrations of carbon monoxide gas and little or no hydrogen-this is pumped out of the flue stacks and causes pollution. The LanzaTech Process captures the carbon monoxide gas from steel mills - gases are scrubbed, cooled and sent to a bioreactor.The carbon component is used as a food source for the proprietary LanzaTech microbes during the biofermentation process. The microbes use this energy to produce ethanol. The LanzaTech process can also use syngas from municipal waste, tires, and waste wood can. Model: Varies. Ideally, joint venture, LanzaTch brings intellectual property and ability to operate plants, and partner brings gas and land. Some joint venture partners may also provide investment. Past milestones: 1. Completion of a pilot plant, now producing 5,000 gallons of ethanol per year based on a 1000-liter capacity. Installed cost was $5 million. 2. Getting a steel mill (New Zealand's BlueScope Steel) to be interested in ethanol as an added-value co-product, and commercially confirming that interest through the operation of the pilot. 3. Developing operations plan suitable for a hazardous operating environment such as an industrial-scale steel mill - including the development of an industrial-scale complete health & safety plan.( ( Future milestones: 1. Completion of a demonstration-scale, 500,000 gallon per year plant. Now looking for site. Engineering is in place, but looking for site, and final costing will depend on site selection. Installation will take eight months, and the company expects to reach this milestone by the end of 2010. 2. 40 Mgy ethanol production by 2013 with completion of first commercial plant. 3. Look for the company to be based in New Zealand, but develop primarily for the larger markets, with a focus on Australia and the US. CEO Sean Simpson recently completed a trip to China, which manufactures as much as 50 percent of the world's steel - "could be a huge market for us, down the road." Metrics: Competitive with $40 oil, excluding the potential value of carbon credits. Sean Simpson (CEO) quotable quotes: "No biofuels company develops just for New Zealand. We're a country here of 4 million people. This is home, where the IP is developed, but the near-term opportunities lie elsewhere. Down the road, there are big opportunities here based on gasification of wood. But in the end, you hope to do a lot of business elsewhere and bring it back home." PetroAlgae Based in: Florida Business: Developer of microcrops. PetroAlgae has developed a new highly nutritional product for animal feed and human food markets. This plant-based protein will provide an alternative for fishmeal, protein concentrates and isolates in current market segments. It is derived from a photosynthetic aquatic micro-crop, cultivated under controlled conditions to produce an organism with a consistent makeup. The price of the PetroAlgae protein compares favorably with soy concentrate and fishmeal on a price per unit protein basis. The amino acid profile of the PetroAlgae protein compares well with a leading soy protein isolate and fishmeal. In initial testing, the PetroAlgae lysine content per gram of protein is higher than both soy protein and fishmeal while comparing closely with two other essential amino acids, methionine and threonine. Additionally, the glutamic acid content of the PetroAlgae protein is lower than soy which may prove to lessen allergenic responses. Digestibility and feeding trials for a range of animals are underway in the U.S. Literature suggests that the PetroAlgae micro-crop protein will effectively support animal nutrition and growth. Model: Licensor Past milestones: PetroAlgae was most recently in the news with expansion of their international sales staff to 28 people. Licensing commenced earlier this spring with an Asian deal focused on China and part of southern Japan. The company's model farm is 12,500 acres and produces 60 Mgy of fuel and as much or more value in proteins, according to company execs. In all, PetroAlgae added nine representatives in North America, South America, Europe, Asia, and the Middle East. The new team members bring experience from BP, ConocoPhillips, Cargill, Trinity Industries, Merrill Lynch and Syngenta. The company has grown to an employee base of 115, up 28 percent from the 90 staff that company has on the payrolls in December. The company now has virtually all of the elements in place to meet its goal of bringing its micro-crop technology to market this year giving PetroAlgae the first-mover advantage in a multi-billion dollar renewable-fuels market, said PetroAlgae Chairman Dr. John Scott. An update on PetroAlgae's progress appeared in the Digest last month, in which the company said that it believes it is the closest company to commercialization of micro crops as a biofuel, will complete its microcrop demonstration farm in Florida this year and will commence booking revenues from technology licenses this year. PetroAlgae management said that it is in discussions with customers in China, India, Japan, Italy, Portugal, Spain, Germany, the UK., Singapore, Finland and the U.S. In March, the company announced that GTB Power had signed to use or sublicense PetroAlgae technology to construct and operate ten facilities in the China, Taiwan, and the Japanese island of Yonaguni. Chairman John Scott said in a statement to shareholders that PetroAlgaes business model is designed to generate revenues from licensing its technology (production systems, micro-crop strains, process controls, etc.) to those with the capital and market know-how to become high-volume producers. We consider our model to be the lowest-risk path to market-strength in what can be a high-risk, emerging industry. We are selling the tools that will allow producers to operate with maximum efficiency in a price-sensitive, competitive environment." The company has refocused its position around a broader group of micro-crops including macroalgae, microalgae, diatoms, micro-angiosperms, and cyanobacteria that can be harvested daily, making maximum use of land, water and energy, and requiring water, nutrients, carbon dioxide and sunlight, and non-arable land. We select the best microorganism for each specific location, indigenous to the region, said Scott, and then apply our distinct proprietary processes to scale from a microorganism to a high output-producing micro-crop. Future milestones: Selling of additional licenses; vcompletion of commercial-scale facilities. Metrics: The company revealed that it is generating 40 grams per square meter per day production levels - equivalent to 400 kilograms of biomass per hectare per day, and that the companys process can now convert carbohydrate content as well as lipids into fuel. Phycal LLC Address: 51 Alpha Park, Highland Heights, OH 44143 Year Founded: 2007 Type of technology: Phycal is developing an integrated production system based on its patent pending technologies for growing algae and extracting energy products, primarily algal oil. Phycal is focused on delivering energy products at a market-competitive price. Algal oil can be converted into biodiesel, or refined into renewable, drop-in replacements for diesel, jet fuel, and feedstock for other energy products. Phycals core technologies include: 1. Olexal Non-destructive extraction ("milking") of oil from algae. Phycals patent-pending non-destructive extraction process, Olexal, milks the oil from algae while maintaining their viability. The milked algae are recycled to the ponds to grow more oil. Olexal requires no dewatering, kills competitors and contaminants, and increases both biomass productivity and lipid accumulation. 2. Heteroboost"!, a hybrid 2-stage phototrophic (sunlight & CO2) and heterotrophic (fixed carbon) system for optimum economic yield of oil from algae. Phycal s production system also deploys the patent-pending Heteroboost"! technology. It starts with a phototrophic first stage to grow biomass and lipid to optimum levels with sunlight and CO2 and then moves algae to a heterotrophic second stage which provides fixed carbon (e.g. inedible sugar) to the algae that quickly and dramatically boosts oil and biomass. This hybrid system synergistically combines the benefits of what is achievable through purely phototrophic or heterotrophic growth. Fuel Type: Phycal produces commodity energy products from algae, primarily algal oil, as a feedstock for partners who will convert Phycal's algal oil to renewable diesel, biodiesel, renewable jet fuel, and renewable naphtha. Major investors: Logos Energy, Inc. 3 top milestones for 2008-09: 1. In June 2008, the company opened their subpilot-scale plant. This subpilot was built to scale-up all unit operations from laboratory-scale to the next technology readiness level. At the subpilot technology readiness level, the goal is to scale-up, develop, and integrate all unit processes into a continuous system in a relevant environment. This is the last level necessary before implementation at the pilot/demonstration level. To achieve this, Phycal has to date installed and developed: outdoor ponds, 3 prototype iterations on Olexal non-destructive extraction unit, 2 prototype iterations on Heteroboost"! hybrid growth system, a low-cost primary dewatering process, an aqueous extraction process, a water treatment process, a distillation process, and process logic controls. Phycal submitted multiple patent applications as a result of this subpilot development. In October 2009, Phycal constructed the first pilot-scale skid-mounted Olexal and Heteroboost units for shakedown and preparation for pilot installation. 2. In June 2008, the company completed a preliminary design and executed a lease for a 30+ acre pilot site in Hawaii. This pilot will be capable of 100,000+ gallons of algal oil per year. As part of the pilot, the State of Hawaii has committed cost share. Collaboration was secured with potential customer and customer's customer. 3. In September 2009, the company delivered algal oil under an Air Force contract. 3 major milestone goals for 2010-11: 1. Raise funds for pilot plant and operations in Hawaii with combination of federal and state awards and venture capital. 2. Construction, commissioning, and commencement of pilot plant operations in Hawaii. 3. Verify that pilot plant operating parameters meet cost model assumptions for $4/gal algal oil. Business model: Phycal will partially own and operate project-financed commercial algal oil production facilities. The company may also choose to license unit processes. Fuel cost: Target cost for first commercial facility in Hawaii is $4 per gallon of algal oil by 2016 with natural algae, without an operating subsidy, and including an adequate return to capital. Rollout of follow-on farms in contiguous U.S. will drive to $1-2 per gallon with transgenic algae and continuous improvement. Competitive edge: Phycal's primary differentiators and competitive edge are from the access and development of breakthrough technology and a culture of execution. Both the Olexal non-destructive extraction technology and Heteroboost"! growth system fundamentally change the production of algal oil. See their value propositions in tables below. The tremendous advantages of Olexal and Heteroboost can only be realized if successfully executed. Phycal has built an execution culture based on the integration of scientists and engineers. Working together provides broad perspectives where the biology and system-wide implications are understood so that knowledge is deployed quickly. Table 1 - Value Proposition of Olexal Direct AdvantagesIndirect AdvantagesCommercial Advantages (i.e. How Olexal reduces CapEx and OpEx)The recycling of viable algae back to ponds after lipid milking to grow more lipids Decouples production of oil from production of biomass (i.e., do not need to grow more biomass to grow more oil) Energy, nutrients, and CO2 go more directly to oil production instead of algal cell production Allows continuous algal oil production instead of traditional batch processing which reduces inoculum and grow-up space and time Oil extraction can begin in inoculum ponds thus converting into active area Increases overall system efficiency and benefits energy balance Reduced nutrient supply chain and pumping of CO2 Reduced land requirement and greater percentage of land is active areaEliminates or reduces dewatering Reduces system complexity Reduced dewatering chemicals that must be handled up- and downstream Eliminates or reduces costs of an entire unit processThe removal of chemical algal growth inhibitors (i.e. algal waste) Algae cannot signal to each other that they are too crowded Higher culture densities Increased both biomass and lipid productivity. Higher return to capital for ponds Reduced land requirementThe reduction or elimination of algal predators and competitors Dramatically reduces risk of culture crash Extends open pond production for many weeks instead of a few days Decreases amount of inoculum Reduces both scheduled and unscheduled downtime Increases Overall Equipment Effectiveness (OEE) Reduced land requirement because of reduced inoculum Higher return to capital for pondsExtracts only non-polar lipids and not impurities (e.g. chlorophyll, gums, phospholipids)" Higher quality product " Reduces purification burden" Lower purification costs Table 2 - Technical Value Proposition of Heteroboost"! Technology Direct AdvantagesIndirect AdvantagesCommercial Advantages (i.e. How Heteroboost reduces CapEx and OpEx)The use of phototrophically grown biomass as a feedstock to rapidly produce additional lipid and biomass heterotrophically Decouples production of oil from phototrophic production of biomass (i.e., do not need to grow more biomass to grow more oil) Fixed carbon provided goes more directly to oil production instead of algal cell production Increased both biomass and lipid productivity Increases overall system efficiency and benefits energy balance Reduced land requirement and greater percentage of land is active area Increased oil production from fixed set of biomassModify the lipid profile of the algal strain by metabolism shift Algae appear to use different metabolic pathways for lipid production under heterotrophic growth allowing selection of different lipid end products Different carbon sources provide different end products Higher value lipid product of better product specifications for customer satisfaction Flexibility in the production system to tailor end products to customer useAbility to use fixed carbon from inexpensive sources such as lignocellulosic industry Take advantage of the rapidly developing lignocellulosic industry as it develops sugars targeted to ethanol production Offer an alternative fuel for producers of lignocellulosic derived sugars to ethanol that is more energy dense (and a direct drop in for current fuels). Potentially provide more bang for the buck from lignocellulosic sugars as they are shuttled via respiratory metabolism to useful end products (vs. fermentative pathways for ethanol). Lower cost fixed carbon sources Provide flexibility to lignocellulosic sugar producers. Stage: Currently at subpilot. Pilot will be operational in 2010 at 100,000+ gallons of algal oil per year. Website URL. HYPERLINK "http://www.phycal.com"www.phycal.com Piedmont Biofuels Based in: 220 Lorax Lane, PO Box 661, Pittsboro, NC 27312 Year Founded: Cooperative division founded in 2002, Industrial division in 2005 Technology: Esterification, Transesterication, Flash Evaporation, Acidification, Enzymatic refining Fuel type: Sustainable Biodiesel, Acid Oil, Fatty Acid Distillates, and Refined Glycerol Major investors: Privately funded. Past milestones (08-09): 1. Awarded a $197,000 grant from the North Carolina Biofuels Center to conduct enzymatic biodiesel production. The research is a collaborative effort with Novozymes and Chatham County Economic Development Corporation (CEDC). 2. Commissioned the first biorefinery in North Carolina and therefore expanding biobased product refining capabilities. Part of the Biorefinery installation included the development of biobased fuel application for on-site boiler heat. 3. The first and only small commercial producer to receive BQ-9000 accreditation by the National Biodiesel Accreditation Commission in United States. Currently Piedmont Biofuels continues to be the only BQ-9000 accredited producer in the state of North Carolina. 3 major milestone goals (2010-11) Operate Pilot-scale enzymatic biodiesel production on low value feedstocks like brown and trap greases Combined Heat Power application utilizing biomass based diesel integrated into biodiesel production and the local utility grid. Utility-scale bioheat installation for small town application across the US Business model: LLC partnered with a membership distribution cooperative for retail fueling. Fuel cost: Retail and wholesale capabilities Competitive edge: Piedmonts industry strengths are linked to its commitment to fuel quality, customer service and education. We have been educating public and private sectors about biodiesel since our cooperative formation in 2002. We are a leading institution for experiential education in the biodiesel industry. As the only BQ-9000 producer in North Carolina, Piedmont is the only local provider that can fuel many government and municipal fleets with biodiesel with our high quality biodiesel. We also have a unique model of integration with all facets of feedstock collection, commercial production, a co-located biorefinery for co-products, retail and wholesale distribution capabilities, on-site analytical laboratory, engineering, and fabrication services. Plankton Power 1. Company name: Plankton Power Based in: 395 Kendrick Avenue, Wellfleet, MA 02667 Year Founded: 2007 Annual Revenues: $500,000 (projected), $0, $0 Technology: Integrated Algae Biorefinery/Transesterification for biodiesel step Fuel type: Biodiesel, Jet Fuel, Helicopter Fuel Major investors: Private Equity Past milestones (08-09): Confirmed Project Location at Massachusetts Military Reservation (10 Acre Pilot) integrated with Landfill gas recovery, Formation of World Class Project team with Woods Hole Oceanographic Institution, Marine Biological Laboratory, Cape Cod Commission & Regional Technology Development Corporation for $20 million DOE FOA; Production demonstration of 1 million gallons per year per acre in Argentina (3 month field trial results). 3 major milestone goals (2010-11) Completion of 5 Acre Pilot facility, producing 1 million gallons per year; initial commercial facility development with gulf coast refinery and initial pilot location scale-up to 100 acres and 100 million gallons per year production Business model: Build, Own, Operate under joint ventures Fuel cost: $1.40 - $2.00/gallon (commercial scale projection) Competitive edge: Comparisons with DOE Aquatic Species Program open pond production levels of 2,000-4,000 gallons per acre per year: 1. Closed Pond 5 times improvement lack of predators, virus, bacteria, impacts of rain and snow 2. Integrated Proprietary Technology Combined pond and photobioreactor 6 days growth in one day 3. Oil Trigger Mechanism Gellification/Stress Cycle (2-3x improvement natural = 20-35% 50%-65%) 4. Normalize for Pond Volume Normal pond is 1 foot, we have a 5x improvement with a nearly 5 foot depth and full exposure of volume to light 5. Temperature Constant temperature control 5-10x improvement 6. Light Constant light & proper wavelengths 5-10x improvement 7. Species selection 3-5x improvement over local wild strains, fresh water and or warm water species 8. Nutrients Specialized micronutrient profile, algae recycling, etc.1-2x improvement 9. Concentrated CO2 use of concentrated CO2 compared with natural CO2 10x improvement 10. Salinity Proprietary salinity level unknown major advance 11. Major new low energy dewatering and extraction system Alliances and Partnerships: Distribution is through existing channels and with more available demand than supply and includes 3 of New Englands largest biodiesel distributors. Marketing, research and production partnerships are listed above. Development stage The technology is commercial ready. Platform is being migrated to the US for initial validation on a long production run, before moving to commercial fundraising and construction. Website URL HYPERLINK "http://www.planktonpower.com/"www.planktonpower.com Praj Industries Limited Based in: Praj House, Bavdhan, Pune 411021. India Year Founded: 1984 Annual Revenues 2009 Projected : US $ 187 M 2008 Audited : US $ 159 M 2007 Audited : US $ 145 M Type of Technology Fermentation, Distillation, Dehydration, Evaporation, waste-water treatment and re-utilization, for first generation bioethanol and esterification, trans-esterification, technologies for biodiesel plants. Second and Third generation under pilot-scale and lab scale respectively. Type of fuel Turnkey solutions to install plant and equipment to produce bioethanol and biodiesel from 1st and 2nd generation energy crops 3 top milestones for 2008-09 1. Inaugurated Lignocellulose to Ethanol pilot plant 2. Inaugurated first-of-its-kind zero discharge wastewater plant wherein Praj supplied its patented self cleaning, extended operation evaporation system. 3. Energy efficient ethanol plants in Europe for Biowanze, Belgium and Anklam Biofuels, Germany. 3 Major milestone goals for 2010-11 1. To offer alternate, low carbon footprint, Farm-to-Fuel modules for biofuels 2. To achieve critical milestones in Lignocellulosic biomass to ethanol production 3. To establish a Pilot plant for algae to biodiesel Business Model Complete services under one roof for biofuel plants Competitive edge Technology, experience, own manufacturing units, global presence and R & D backed solutions Distribution Praj is operating across 5 continents with over 450 references Stage Praj offers entire solutions right from concept to commissioning for installing biofuel comple Website www.praj.net Price BIOstock Address: Monticello, AR Year Founded: 1965 for The Price Companies, Inc., the parent company. 2006 for the Price BIOstock, Inc. division. Business Model: Wood and the black liquor that is a residue of the paper/pulp making process are biofuels. Over 60% of the electricity needed to power the mills come from these residues. Heat and steam are byproducts of wood combustion and gasification. The Price Companies is one of the largest and most experienced wood processing companies in the U.S. with 20 facilities nationwide under contract for many of the most respected paper/pulp mills in America (including International Paper, Rayonier, Weyerhaeuser, New Page, and Georgia Pacific). Price BIOstock is their division focused on supplying biomass feedstock for the emerging bioenergy industry. Typically, Price capitalizes, builds, and operates the preparation facility while the customer pays a price per ton for the fully prepared feedstock. Type of technology: Customized biomass feedstock aggregation, transport, and preparation (usually wood chipping) for use by any biorefinery or biopower plant. Fuel Type: Current production of over 14.5 million tons of wood chips for conversion to pulp, paper, and black liquor used to fuel power production in 2008. Production of over 2.5 million tons of hog fuel for combustion. New uses for wood chips include co-firing and combustion to generate biopower to meet RPS and RES standards; thermochemical or biochemical conversion to biofuels to meet RFS standards. Future uses for biomass pellets include torrefaction for drop-in replacement for coal. 3 top milestones for 2008-09: 1. Secured contract for feedstock aggregation and receiving yard design and construction for Range Fuels, Inc. (ranked #5 in 2008) wood-to-ethanol biorefinery in Soperton, GA. 2. Signed a strategic alliance with Raven Biofuels (#26 in 2008) for building a chipping facility in British Columbia using bug-infested wood for feedstock to produce ethanol. 3. Signed a MOU with Zeachem (#11 in 2008) for supplying wood chips for their first demonstration facilities. 3 major milestone goals for 2010-11: 1. Complete the construction and commissioning of the receiving yard and feedstock preparation facility for Range Fuels, Inc. project. 2. Help site and complete contracts for several biofuels and biopower projects in the Southeastern U.S. 3. Consult and complete contracts with wood plantation and energy crop producers for supply of biomass for bioenergy production. Fuel cost: Price of biomass varies per location, feedstock specification, and annual volume requirements. Prices are indexed to agreed to indicators to protect all parties from fluctuations in feedstock prices. Competitive edge(s): Strong relationships with timberland owners and forest products community. Strong network of foresters and equipment suppliers. Existing relationships with major producers of wood residues. Time-tested systems for technology, IT, payroll, insurance, and employee training. Demonstrable management experience in all phases of biomass aggregation and preparation. Price BIOstock quotable quotes: "Producing billions of gallons of ethanol will require millions of tons of cellulosic feedstocks. Moving that feedstock efficiently, safely and with as little impact on infrastructure and the environment as possible will be a major challenge in the years ahead." Biomass Magazine article on Price BIOstock 4/2008 "Let me get this straight. You procure and prepare the feedstock so... we don't have to?" - prospect's summary of a closing argument. "[We have] a business relationship with most chip handling and wood processing companies in the USA. The Price Companies has exceeded all our expectations from customer service to chip quality on the chip pile. We look forward to the strengthening of our win-win relationship in the future." - testimonial from a satisfied paper/pulp mill customer. "Acquiring biomass is labor intensive and it involves building solid business relationships with landowners." enerG article on Price BIOstock 5/2009 "The Price Companies have a better understanding of the customer/supplier relationship than anyone I've ever worked with. They are always able to match their production to [our] needs." - testimonial from another satisfied paper/pulp mill customer. "Biomass supply made simple." - Price BIOstock company slogan. Website URL:  HYPERLINK "http://www.pricebiostock.com" http://www.pricebiostock.com Pure Vision Technology Based in:511 McKinley Avenue, Fort Lupton, CO 80621 Year Founded:1992 Annual Revenues:2009 - $250k (Projected), 2008 - $309k, 2007- $780k Technology: Front-end Biomass Fractionation for production of inexpensive sugars for the biofuels fermentation industry Fuel type: Extract separate sugars and lignin streams from biomass for downstream conversion to cellulosic ethanol, butanol, next-generation drop-in biofuels or biochemicals Major investors: Officers, Friends & Family --- currently preparing for round A financing Past milestones (08-09): First sale of equipment, Formation of spin-off companies for marketing PureVision technology, Purchase and operation of pilot Fractionator at 0.5-ton/day 3 major milestone goals (2010-11) Round A financing, Integrated demonstrationat 20-ton/day, Design of commercial-scale plantat 250-ton/day Business model: Equipment and process sales, licensing and sublicensing fees, and royalty licensing per thousanddry tonnes of biomass fractionated Fuel cost: Commercial target of 10-cents per dry pound sugar. Projected impact on downstream cost of biofuels is a 10-20% reduction pergallon, with an expansionin feedstocks to all cellulosic material. Competitive edge: PureVision Biomass Fractionation Process effectively and efficiently separates lignocellulosics biomass into useful intermediate components including cellulose fiber, xylose-rich syrup, lignin and biogrowth media. The high purity, high yeild cellulose fiber is available for pulp applications or efficienthydrolysis to glucose. The energetically-dense glucose and xylose syrups can be converted, via thermochemical or biocatalytic routes, to ethanol, butanol, andmany other chemicals. The sulfur-free, highly-depolymerized, energetically-dense lignin can be converted to biofuels or used directly as boiler fuel. The low-toxicity extractives-rich liquor is a suitable biogrowth media to produce yeast feed protein or for biocatalyst propagation. The flexibility of the front-end PureVision Biomass FractionationProcess to producediverse fractionated product streams provides a hedge against the volatile fuelmarket; and allows for future technological upgrades to higher-value fuels and chemicals. Alliances and Partnerships: Century Extrusion is a strategic manufacturing partner with the ability to rapidly build and ship finished units worldwide. ICM has filed for a DOE grant with PureVision as a sub-contractor to provide front end fractionation for a pilot plant. An agreement is in place regardless of grants to co-locate a PureVision Fractionatorat their facility in St. Joseph,Missouri. Gevo has also filed for a DOE grant with PureVision to provide commercial demonstration of anintegrated biorefinery with cellulosic feedstock. Microbiogen Pty Ltd. is the world's leading non-GMO yeast developer and has an agreement with PureVision to co-develop an integrated process for maximizing yields from the PureVisionprocess for multiple cellulosic feedstocks. Numerous other strategic partnershipsare inprocess with technology companies, energy companies and foreign governments and companies to provide front end fractionation forcellulosic feedstocks. Development stage: Pilot, with aworking 1/2-ton per dayscale Fractionator producing data to be used in the design of a 20-ton per day scale Fractionator in 2010. A commercial-scale 250-ton per day Fractionator is scheduled for 2012, with first units shippedin that year. Website: HYPERLINK "http://www.purevisiontechnology.com/"www.purevisiontechnology.com Remediation Earth, Inc. Address: 4607 Lakeview Canyon Rd, Suite # 438, Westlake Village, CA 91361 Year Founded: 2007 Type of technology: Pyrolysis & anaerobic gasification Fuel type: Synthetic diesel, transportation grade green diesel, #2 fuel oil Major investors: Currently supported by private investors 3 top milestones for 2008-09: A) Signed the exclusive license agreement for all of North America with our Japanese technology partner B) Secured our first long-term (20 year) material recovery facility (MRF) contract in San Bernardino, CA C) Recently started lease on new 42,000 ft2 building for our new pyrolysis facility 3 major milestone goals for 2010-11: A) Have first commercially operating pyrolytic system that converts plastic and medical waste to fuel, which meets SCAQMDs emission standards. B) Complete the development of our Pyrolysis II anaerobic gasification system with integral Fischer Tropsch section. C) Integrate our chemical-free and CA-EPA registered wastewater technology and our new power generation capabilities with our thermo-conversion technologies in a highly synergistic manner. Business model: Equipment sale, lease, build, own/operate (BOO) Fuel cost: Less than $1.00/gallon, using our current Pro Forma Competitive edge: Our pyrolysis process is proven commercial technology (over 15 years), and is enhanced using our patented real-time remote prognostic health monitoring (PHM) system. We address environmental issues with our ability to convert a wide variety of feedstocks into valuable energy products, including synthetic diesel, #2 fuel oil, transportation grade biofuels, electricity, carbon black and bio char, and H2 gas from pyro-liquids. And the system emissions are well below EU and US limits. We have over 20 years experience using a modular system approach. Distribution, research, marketing or production partnerships or alliances: Plants In A BoxTM joint venture; Inland Empire Environmental partnership Stage: Commercial, with shovel-ready projects Website URL: www.RemediationEarth.com Remfuel Bioenergy Private Limited Based in: India 2008-09 ranking: Unranked Business: Conversion of Straight Vegetable Oils (SVO), including Algal Oils to Biodiesel blendsWITHOUT the need for transesterification. Also aNovel non-food sourcefor Biodieselwithout the need for Transesterification is also ready for commercialization. Model: License technology(s) for commercial use; existing SVO plantations will benefit from reduction in capital costs. Metrics: REMB-1: A novel biodiesel source has been identified and the technology has been patented under PCT. REMB-2: A new generation biodiesel additive (patent-filed), which results in completely eliminating the need for transesterification. Capital costs and process costs help bring down biodiesel blend costs by over 30%. Both of these novel technologies improve fuel efficiency and significantly reduce emissions; have been validated and are ready for commercialization. Year Founded: 2000 Annual Revenues: Bigtec Labs 2007: US$ 2.2 million 2008: US$ 4.6 million 2009 (projected): US$ 6 million Technology: Our focus is on developing biofuel technologies, which eliminate transesterification for straight vegetable oil (SVO), animal fat oil and algal oil. Our first technology (REMB-1) is based on a new biodiesel source, which generates multi-fold income to the farmer compared to traditional biodiesel sources like Jatropha and requires no transesterification. The cultivation of this tree also generates an exotic food for human consumption. Novelty of this technology invention is established by acceptance of all 38 claims by PCT as novel and patentable (PCT filed) Our second technology (REMB-2) is a fuel additive, which makes SVO to work as a drop-in bio-fuel to blend into diesel. This essentially eliminates the transesterification of fats, and allows any SVO, animal fat oil and algal oil to be used directly as a diesel blend. Our technology saves over 30% of manufacturing costs and an independent patent search report indicates that our technology is unique & patentable. Both of our technologies have been independently evaluated on different diesel engines and the emission, combustion and performance of our biofuel blends are on par or better than commercially available diesels and biodiesels. Fuel type: 1.Biodieselblend, no transesterification 2.Fuel additives that eliminate transesterification and make SVO, Animal Fats and Algal Oil into drop-in Biodiesel blends 7. Major investors Funded by the parent company bigtec Holdings Private Limited 8. 3 top milestones for 2008-09 Development of fuel additives which eliminate need for transesterification Blending agents for gasoline and algal fuel (no transesterification) New plant oils, which do not require transesterification 9. 3 major milestone goals for 2010-11 Licensing/Commercialization of biofuel technologies, which eliminate transesterification Development of open-pond stable algal strain Converting plant biomass to biofuel Business model: Develop novel biofuel technologies, validate & license the technologies 11. *Fuel cost (per gallon) REMB-1 - New biofuel blend: US $ 1.3/gallon REMB-2 - Biodiesel fuel additive: US$ 1.5/ gallon 12. Competitive edge(s): (e.g. Distribution, economies of scale, low-cost, quality, location, vertically integrated model, location, yield, genetics) REMB-1 Unique plant-based fuel source, with no transesterification needs, which also generates food, and provides multi-fold farm income, compared to traditional biodiesel sources. REMB-2 Our fuel additive completely eliminates the need for transesterification of any traditionally used oils and cuts biodiesel production cost by over 30%. 13. Distribution, research, marketing or production partnerships or alliances We have a dedicated R&D team focused on developing innovative technologies in biofuels and are in the process of licensing/commercializing our technologies. We do not have any research partnerships and the research is exclusively the outcome of concerted in house R&D efforts. Development stage Independent research institutions have validated our new biofuel and biodiesel additive technologies and we are in the process of licensing/commercializing these technologies. 15. Website URL HYPERLINK "http://www.remfuelbioenergy.com/"www.remfuelbioenergy.com HYPERLINK "http://www.bigteclabs.com/"www.bigteclabs.com Renewable Energy Group (REG) Based in: 416 S. Bell Ave. PO Box 888, Ames IA 50014 Year Founded. 2006. In biodiesel production since 1996 through predecessor company, West Central. Annual revenues: For the Year Ended December31, 2008, $85.5 million Type of technology Biodiesel Currently: Transesterification Patent-pending cold filtration post-production process Proprietary pretreatment process Biojet fuels Active research partnership for purification/pretreatment of natural oils Type(s) of fuel produced: REG-9000TM branded biodiesel product lineup REG-9000/1 REG-9000/5 REG-9000/10 REG Glycerin, high quality, consistent crude glycerin Major investors Biofuels Company of America, LLC Bunge North America, Inc. ED& F Man Natural Gas Partners NGP Energy Technology Partners, L.P. USRG West Central Cooperative 3 top milestones for 2008-09 Successfully introduced REG-9000TM brand and product line REG acquisition and technology upgrades of 35 mmgy Houston biodiesel production facility designed by Lurgi Technology upgrades to allow 45 mmgy facility to utilize high free fatty acid feedstocks; achievement of BQ-9000 Accreditation all at Blackhawk Biofuels, LLC Construction and completion of REG Research Center for feedstock commercialization and fuel quality testing 3 major milestone goals for 2010-11 -Continue to expand our core business through product development, market research and feedstock utilization and innovation -Create and maintain partnerships that connect REG in the renewable fuels and renewable chemical industries -Expand our user reach across both end-user platforms and geography Business model: REG-9000TM biodiesel is produced by REG network production facilities consisting of state-of-the-art, proprietary multiple-feedstock technology. The REG network includes wholly owned and third-party owned facilities for a total production capacity of 302 million gallons. REG-9000 TM biodiesel is marketed through large petroleum companies and fuel distributors, and is utilized by on-highway fleets, municipalities, and power generator, mining, military, home heating and agriculture applications. Fuel cost: Competitive with No. 2 diesel fuel Competitive edge: Research, Technology and Development REG believes that universal compatibility is the fastest means to procure the volumes of feedstock needed for large-scale commercialization. REG can augment current pre-treatment and production of multi-feedstock biodiesel in continually increasing volumes as part of their current continuous-flow, commercial-scale process technology. Pilot scale feedstock pretreatment and ASTM-exceeding biodiesel production Variety of algae oil strains Jatropha Coconut oil Moringa Peanut oil Camelina 25 additional novel feedstock = Commercial scale feedstock pretreatment and ASTM exceeding biodiesel production (produced at one of REGs network facilities either through marketed product or toll agreement) Four grades of soybean oil Four grades of canola oil Three grades of palm oil Waste corn oil (extracted from distillers grains) Three grades of beef tallow Three grades of pork lard (including bacon fat) Poultry fats Yellow greases Used cooking oil REG Research Center The companys new 3,000+ sq. foot laboratory serves as the hub for feedstock technology, development and commercialization programs. The REG Research Center staff conducts fuel quality analysis and feedstock commercialization research for the REG network of biodiesel production facilities and others in the biofuels industry. REGs core feedstock and technology development team consists of a director, business development manager, two PhD chemists and several biochemical and research engineers.This core team leverages the work done by REGs technology team which consists of approximately 30 industry leaders in plant engineering and diesel supply chain integration. This asset of knowledge and experience focuses on improving production volumes and quality, evaluating potential new feedstock sources and new technologies, designing and improving equipment and the process flow, enhancing the value of co-products, troubleshooting and educating customers and strategic partners. Commercial Scale Capabilities Current REG network biodiesel production capacity: 302 million gallons at nine facilities Began commercial scale biodiesel production in 2006 Utilizes a multi-feedstock approach to biodiesel production; more than 20 feedstock regularly used to produce REG-9000 products Every biodiesel production facility has laboratory on-site Proprietary pretreatment process Every gallon of biodiesel is post-treated using a patent-pending cold filtration system By defining the processing parameters for new feedstock such as algae, jatropha, camelina or other fats and oils in the REG Research Center, the company can then process those feedstock using REGs commercial scale pretreatment and production technologies. Biodiesel Product Marketing, Sales and Distribution Marketed approximately 94million gallons of ASTMD6751 certified biodiesel in 2008; approximately 20 percent of all biodiesel used in the U.S. REG-9000 biodiesel product line up which is marketed on fuel characteristics, not feedstock BQ-9000 Producers: six REG network facilities have achieved BQ-9000 status BQ-9000 Marketers National infrastructure with more than 20 terminal locations Rail fleet: more than 300 rail tankers to transport B100 and B99.9 nationwide, REG utilizes placite lining to protect biodiesel quality through transport Alliances and Partnerships: Research General Atomics: Battlefield Clutter program- dissolving battlefield plastic waste into biodiesel then using the fuel to power frontline generators and DARPA funded research on algae oil to jet fuel Elevance: Active research partnership for production of biojet and enhanced biodiesel fuels and specialty chemicals Solazyme: Ongoing research in the pretreatment and conversion of algae oil to biodiesel Univenture/Algaeventure Systems: supporting their research to harvest, dewater and dry algae UOP and the University of North Dakota EERC: supporting their biojet production system research by assisting in feedstock pretreatment and supply Catilin: Supplying support for their research into a biodiesel heterogeneous catalyst Kemin Industries: Research collaboration for biodiesel oxidative stability products Iowa State University: Oleaginous yeast oil research project; partnership in General Atomics and biodiesel moisture retention projects Kansas University: emissions testing of B5, B10 and B20 in General Electric locomotive engine operated by Iowa Interstate Railroad University of Northern Iowa: soy methyl ester lubricant testing Iowa Central Community College: Two Million Mile Haul, an over-the-road demonstration of B20 in conjunction with Caterpillar, Iowa Soybean Association and Decker Truck Line; as well as biodiesel filter research Biofuels Digest 50 Hottest: Several of the 2008 Biofuels Digest Hottest renewable fuel companies have ongoing collaborations with REG in the areas of feedstock pretreatment and supply. Marketing/Distribution partnerships: REG network: Management and operations services agreements with seven biodiesel plants (250+ mmgy production capacity) including feedstock procurement, production, operations and marketing Maple River Energy, Galva, IA: agreement to market biodiesel from 5 mmgy biodiesel plant Alta Fuels, Alamosa, CO: terminal agreement and localized marketing Kellerstrass Oil, Ogden, UT; terminal agreement and localized marketing Mining industry: partnerships with several underground mines meet MSHA diesel particulate matter using high biodiesel blends Clean Cities: biodiesel promotions and marketing partnerships in more than six regions UL biodiesel retail pump evaluation partnership Minnesota Weights and Measures Dept.: evaluation of thermal expansion of biodiesel for proper temperature compensation. ASTM active committee members Development stage Renewable Energy Group (REG) is a leader in the biodiesel industry by offering a complete biodiesel solution. Renewable Energy Group offers procurement and risk management, production operations, and technology services on a commercial scale level in addition to alternative feedstock research and commercialization which include lab and pilot scale operations. Website URL www.regfuel.com Rentech Based in: 10877 Wilshire Blvd., Suite 710, LA, CA 90024 Year Founded: 1981 Annual Revenues: 2009: Though we do not provide revenue projections, revenue for the last twelve months ended June 30, 2009 is $233 million. 2008: $211 million 2007: $132 million Technology: The Companys Rentech-SilvaGas biomass gasification process is the technology used in the only biomass gasifier operated at commercial scale in the United States. It can convert multiple biomass feedstocks into synthesis gas (syngas) for renewable power production, and can be integrated for conversion of syngas into complex hydrocarbons by the patented Rentech Process based on Fischer-Tropsch chemistry. The final products after upgrading are ultra-clean synthetic jet and diesel fuels, specialty waxes and chemicals Fuel type: Rentech produces drop-in synthetic diesel fuel that meets ASTM-975 specs. Rentechs synthetic jet fuel has been certified by the FAA for commercial aviation use and by the U.S. Air Force for use in its aircraft. All fuels produced by the Rentech Process can be distributed and used in existing infrastructure including pipelines and engines and are cleaner burning than traditional petroleum-derived fuels. Rentech's ultra low sulfur diesel fuel, or RenDiesel, is environmentally friendly. RenDiesel is biodegradable, exceeds all global sulfur requirements and has no aromatics. When compared to traditional petroleum-derived low sulfur diesel, tailpipe emissions from RenDiesel generate lower amounts of hydrocarbons, carbon monoxide, particulate matter, nitrogen oxides (NOX), sulfur oxides (SOX) and carbon dioxide. Also, when compared to traditional diesel fuels, RenDiesel has a higher hydrogen content, heating value and cetane index, making it very energy efficient. RenDiesel also has excellent storage stability making it an ideal fuel for back-up power generators. Depending on the feedstock, the fuels produced by Rentechs technologies can have a lifecycle carbon footprint of near zero. The Companys Rialto Renewable Energy Center, currently under development, is expected to produce diesel fuel from green woody waste, diverting the waste from landfills, and producing fuels with near-zero lifecycle CO2 profile. RenJet, our military and commercial jet fuel, has all of the positive environmental and efficiency benefits of RenDiesel. Moreover, our jet fuel reduces aircraft particulate matter emissions by 96% in engine idle, a major source of ground level pollution. In addition, the lower density of RenJet fuel could enable aircraft to have a lower take-off weight, which conserves fuel and, therefore, lowers fuel consumption and operating costs. Alternatively, the lower density of RenJet fuel could allow aircraft to carry heavier payloads with the same volume of fuel when compared to traditional jet fuel. We have provided synthetic fuels to: the U.S. Air Force for testing in a T-63 turbine engine the U.S. Military for use in a LASSO(R) Utility Vehicle designed and built for the U.S. Military by ICRC/VSE Corporation The University of West Virginia for emissions testing of synthetic fuels with a 4,000 horsepower Norfolk Southern locomotive engine, a 1,000 horsepower Caterpillar engine provided by Walker Equipment and a 96 horsepower underground engine provided by the Mine Safety and Health Administration commercial airlines for testing Major investors: Rentech has been publicly traded since 1991. Our stock trades on the NYSE AMEX under the symbol RTK. Our largest institutional holders are BlackRock Investment Management Company, Wellington Management Company, Barclays Global Investors and the Vanguard Group. Past milestones (08-09): Our 3 top milestones for fiscal year 2009, are as follows: 1. Agreement with eight major airlines to sell renewable diesel for ground equipment: In August 2009, Rentech announced an agreement that included commitments from eight major airlines, that was described by the Air Transport Association (ATA) as a First-of-Its-Kind, unprecedentedagreement to purchase up to 1.5 million gallons per year of renewable synthetic diesel fuel for use in ground service equipment at Los Angeles International Airport. The Chairman of the ATA said, We are proud to take part in this innovative, collective endeavor that, over time, will further reduce greenhouse gas emissions and improve local air quality through the use of greener fuels. The fuel will be supplied by Rentechs Rialto Renewable Energy Center, which is currently under development. The fuel will be produced from green woody waste diverted from landfills, and will have a lifecycle carbon profile of near zero. 2. Jet Fuel certified for commercial aviation by FAA: Our synthetic jet fuel, RenJet, was recently certified by the FAA for use in commercial aviation. In August 2009, ASTM Internationals full governance committee unanimously approved modifying the specifications for commercial aviation jet fuel to include up to a 50/50 blend of synthetic Fischer-Tropsch jet fuel. The jet fuel certified by the Federal Aviation Administration for use in commercial aircraft relies on ASTMs specifications. With the ASTM specifications, fuel derived using the Fischer-Tropsch process, including Rentechs synthetic jet fuel produced from renewable or fossil feedstocks, is the first and currently only alternative jet fuel certified for use by the FAA. We currently produce jet fuel at our Product Demonstration Unit that, when blended with petroleum-derived fuel, meets the ASTM International specifications. 3. We advanced our biomass capabilities through development and acquisition activities: a. We acquired 100% of SilvaGas Corporation and its commercially proven biomass gasification technology, which converts a variety of biomass feedstocks (e.g., wood, agricultural residues, refuse derived fuels and energy crops) into syngas for renewable electric power or synthetic natural gas production. The biomass gasification technology can also be integrated with Rentechs technologies for the production of certified renewable synthetic jet and diesel fuel. The life-cycle carbon footprint of renewable fuels and power facilities using the Rentech-SilvaGas gasifier coupled with the Rentech Fischer-Tropsch Process for synthetic fuels will be near zero. b. We announced the development of our Rialto Renewable Energy Center, which is anticipated to be the first of its kind commercial facility in the country that will convert urban green waste such as yard clippings and tree trimmings into approximately 9 million daily gallons of the cleanest diesel fuel in California and enough renewable electricity to power about 30,000 homes. Our planned Rialto Renewable Energy Center, which is currently in the feasibility engineering phase, will have a carbon footprint of near zero, is expected to create 250 green construction jobs and at least 55 full-time positions. The facility is expected to be operational in late 2012. Some of the diesel we produce at our Rialto Project will fuel ground service equipment at LAX, making LAX one of the greenest and cleanest airports in the country. c. We made a 25% strategic investment in ClearFuels Technology Inc., a biomass gasification and project development company. ClearFuels owns a proprietary flexible biomass gasification technology platform that converts multiple rural cellulosic biomass feedstocks such as sugarcane bagasse and virgin wood waste into clean syngas suitable for integration with synthesis gas-to-liquids technologies. 3 major milestone goals (2010-11) Among our top goals for fiscal year 2010 are: Achieve development milestones for our proposed Rialto Renewable Energy Center: complete front-end engineering and design, file permit applications necessary for construction apply for Loan Guarantee with the U.S. Department of Energy License our technologies for commercial deployment. Identify additional sites for development of clean energy projects using our technologies. Business model: Rentechs business model encompasses being: a developer/owner/operator of synthetic fuels and power facilities (particularly renewable energy facilities) a developer of synthetic fuels and power facilities a licensor of energy conversion technologies of biomass gasification and/or Fischer-Tropsch for the production of synthetic fuels and power facilities from renewable and fossil resources as well as a licensor of biomass gasification technology for repowering coal-fired power plants for production of renewable electricity. Fuel cost: Specific cost per gallon of fuel produced will vary based on feedstock and plant design. The renewable energy facility we are developing in California will use green waste as an input, so feedstock costs will be negative, thereby reducing production costs. We expect that our production costs will allow us to be competitively priced with future market prices for diesel and jet fuels as well as renewable power, while earning attractive returns for our investors Competitive edge: Rentech has several competitive advantages: Integrated biomass-to-fuels technologies ready for commercial deployment. We believe we have a unique combination of integrated technologies, from biomass gasification through syngas cleaning to liquid fuels production that is ready for commercial deployment. This integrated package can produce ultra-clean certified fuels, as well as renewable power, with near-zero carbon lifecycle profiles. We maintain technology leadership. We have an unmatched biomass-to-energy technology chain based on proven technologies. We have a strong patent portfolio of demonstrated biomass gasification and Fischer-Tropsch technologies. In addition, our technology allows for economic small-scale commercial production of renewable synthetic fuels as well as large-scale production of synthetic fuels from fossil resources. Demonstration stage is behind us. We have successfully funded the construction of development-scale plants and operated those plants, giving us significant operating experience with our technologies. Our demonstration plant gives us the ability to test new technologies at demonstration scale at very low incremental cost. This gives us a significant head start and advantage over companies that have yet to fund or build demonstration scale facilities. Operational experience. We constructed and operate the only fully-integrated transportation fuels production facility in the U.S. We have produced thousands of gallons of ultra-clean synthetic fuels including military jet fuel, commercial Jet A and Jet A-1 and ultra-low sulfur diesel have been produced at our facility and have met or exceeded applicable fuels standards. We also have 150 people operating a nitrogen fertilizer plant, and this experience is highly transferrable to the operations of synthetic fuels facilities. Drop-in fuels. Our fuel can be used in existing engines and infrastructure and is the only alternate fuel type certified by the U.S. Air Force and FAA. In addition, our fuels can be used as a neat fuel or as a blend. Project pipeline. We have a pipeline of projects under development for the production of synthetic fuels and power. Strong balance sheet: We have significant cash on our balance sheet and have recently demonstrated our ability to raise capital several times through equity placements. Our fertilizer plant produces significant cash flow, which helps to fund our energy development activities. Alliances and Partnerships: We believe that having the right strategic partners will help us realize our vision of delivering clean energy solutions. The many advantages of the Rentech Process have enabled us to enter into relationships with key strategic partners and, as our business grows, we expect to enter into more of these relationships. Developing relationships with world class technology leaders allows us to provide a more complete product offering to our customers, licensees, and partners. Denbury Resources, Inc. ("Denbury"). Together with gasification and upgrading technologies, the Rentech Process enables us to produce ultra-clean fuels and chemicals that are cleaner than petroleum-based products in terms of regulated emissions (NOX, SOX, and particulates) and carbon dioxide. Our process captures up to 80% of the carbon dioxide generated during the production process. We have entered into an agreement with Denbury, an independent oil and gas company, to sell to them all the carbon dioxide we capture at our proposed large-scale synthetic fuels facility (Natchez Project). Denbury expects to use the CO2 for Enhanced Oil Recovery, which would effectively sequester the carbon. Under this long-term agreement, Denbury plans to build a pipeline to our Natchez facility and transport the captured carbon dioxide underground to depleted oil fields to produce otherwise unrecoverable domestic oil reserves. The CO2 from our Natchez Project will effectively replace naturally occurring CO2 that Denbury is currently extracting from its Jackson Dome deposit. It is estimated that the carbon dioxide generated in the production of one barrel of synthetic fuel like RenDiesel or RenJet will facilitate the production of two additional barrels of crude oil. Our relationship with Denbury will lower the carbon footprint of the Natchez Project as well as help America's efforts to reduce its dependency on imported oil. Moreover, we believe the emissions reducing characteristics of the Rentech Process, together with our alliance with Denbury, will result in our Natchez facility being one of the cleanest fuel production facilities in the country. UOP. UOP, a Honeywell company, whose roots date back to 1914, is the premier refining technology company in the world. UOP's cutting-edge technology advances create higher yields and higher quality products. In addition, they also create cleaner technologies and processes for a healthy environment. Rentech has an agreement with UOP to jointly offer our two companies' respective technologies for the commercial production of ultra-clean synthetic fuels. As commercialization partners, Rentech and UOP expect to increase our market reach and jointly offer proven technologies that can produce products that are cleaner than traditional petroleum-derived fuels and chemicals. Jacobs Engineering Group, Inc (Jacobs). We launched an engineering program with Jacobs Engineering Group Inc., one of the world's largest and most diverse providers of engineering and construction services, to assist us in completing a commercial-scale Reactor Design Package for the Rentech Process. This work will enable us to estimate the capital costs for our reactor. Jacobs is also conducting the feasibility engineering work for our proposed renewable fuels and power facility in California. ClearFuels Technology Inc. ("ClearFuels"). Rentech has made a 25% strategic investment in ClearFuels, a biomass gasification and project development company. ClearFuels will install a demonstration-scale biomass gasifier at our Product Demonstration Unit in Commerce City, Colorado to produce syngas from bagasse, virgin wood waste and other cellulosic feedstocks. The gasifier will be integrated with Rentech's Fischer-Tropsch Process and UOP's upgrading technology to produce high-quality renewable drop-in synthetic jet and diesel fuel at demonstration scale. ClearFuels has begun development of multiple commercial-scale biomass-to-energy projects in the southeastern United States, Hawaii and internationally. These projects will use an integrated ClearFuels-Rentech design pursuant to the licensing agreements and will be co-located at sugar mills and wood processing facilities. The U.S. wood waste projects alone are estimated to have an aggregate annual capacity of more than 100 million gallons of renewable synthetic fuels and 30 MW of renewable power. ENVIRON International (ENVIRON). ENVIRON has been engaged to act as Rentechs consultant and contractor for the permitting process for its proposed Rialto Renewable Energy Center based in Rialto, California. ENVIRON will assist in preparing applications for permits necessary to construct and operate the Rialto Project and also perform technical studies for the environmental documents needed to satisfy the California Environmental Quality Act (CEQA). ENVIRON has been involved in the issuance of major air permits in Californias South Coast Air Quality Management District, the agency to which the Rialto Project is subject, and has long been involved with preparing environmental documentation under CEQA. CH2M Hill. CH2M Hill has been engaged to act as Rentechs consultant and contractor for the permitting process for its proposed synthetic fuels facility near Natchez, Mississippi. CH2M Hill will assist in preparing applications for permits necessary to construct and operate the Natchez Project. Aircraft Service International Group (ASIG). We have signed an unprecedented multi-year agreement to supply eight airlines with up to 1.5 million gallons per year of renewable synthetic diesel (RenDiesel) for ground service equipment operations at Los Angeles International Airport (LAX) beginning in late 2012, when our Rialto Renewable Energy Center, which will produce the fuel, is scheduled to go into service. The initial purchasers under the agreement with ASIG, the entity that provides fueling services to many airlines that operate at LAX, are Alaska Airlines, American Airlines, Continental Airlines, Delta Air Lines, Southwest Airlines, United Airlines, UPS Airlines and US Airways. Additional airline purchasers of RenDiesel can be added under the agreement with ASIG. U.S. Air Force. The U.S. Air Force has purchased our synthetic jet fuel for performance and emissions testing in a turbine engine. The purchase followed the Air Forces laboratory testing of Rentechs synthetic jet fuel, which confirmed that the quality and characteristics of our jet fuel meet the Air Forces specifications for synthetic fuels. Norfolk Southern and Walker Caterpillar. Rentech sponsored several tests of synthetic fuels in various engine types. The University of West Virginia conducted emissions testing of synthetic fuels with a 4,000 horsepower Norfolk Southern locomotive engine, a 1,000 horsepower Caterpillar engine provided by Walker Equipment and a 96 horsepower underground engine provided by the Mine Safety and Health Administration. Initial results of these tests have confirmed that synthetic fuels are cleaner burning than traditional ultra-low sulfur diesel fuels, with lower particulate matter and no visible emissions from the use of these synthetic fuels in the engines. Ongoing testing of synthetic fuels in a fleet of on-road vehicles is continuing for further data collection on fuel efficiency and emissions. Ohio State University and The Wilds. Rentech entered into an agreement to collaborate with the Wilds, one of the largest and most innovative wildlife conservation centers in the world, to study the effect on the entire ecosystem of growing and harvesting biomass and non-food energy crops. The collaboration, which also includes Ohio State University, is being conducted on reclaimed mine lands at the Wilds in Cumberland, Ohio. The study will also examine the utilization of marginal landscapes for the production of perennial, non-food based biofuels, and the potential for bio-sequestration of carbon and other environmental services on reclaimed land. Low Carbon Synthetic Fuels Association (LCSFA). Rentech is a member of the LCSFA, which was formed to Based in: existing legislative and regulatory inequities that have slowed or even hindered the development of advanced biofuels. The LCSFA represents the Biomass-to-Liquids (BtL) industry. One of the cleanest and most proven advanced biofuels, BtL is produced through the gasification of renewable biomass and the subsequent conversion of the gasified biomass using the  HYPERLINK "http://cts.businesswire.com/ct/CT?id=smartlink&div=lcajedejafi&url=http%3A%2F%2Fen.wikipedia.org%2Fwiki%2FFischer%25E2%2580%2593Tropsch_process&esheet=6061599&lan=en_US&anchor=Fischer-Tropsch&index=1" \t "_blank" Fischer-Tropsch synthesis process. The renewable fuels produced are predominantly synthetic diesel and jet fuel, which are nearly identical to current crude oil-derived fuels, although significantly cleaner. Development stage 1. Our Rentech-SilvaGas biomass gasification technology operated at a commercial scale of 400 tons per day 2. Our Product Demonstration Unit is a demonstration scale plant that produces 10 barrels per day of synthetic jet and diesel fuel. It is the only operating integrated synthetic fuels plant operating in the U.S. today. 3. Our Rialto Renewable Energy Center, currently under development, is a commercial scale plant that is expected to generate attractive economic returns for investors, and will employ both our biomass gasification and synthetic fuels production technologies. During our nearly 30-year history, Rentech and our licensees have successfully applied the Rentech Process in facilities ranging in size from pilot scale to 300 barrels per day of synthetic fuels and chemicals production. Our first renewable facility was built in 1992 and used landfill gas to produce alternative fuels. Rentechs technologies have been chosen for demonstration at DOE sponsored facilities; the Rentech Process at DOEs Laporte, TX facility and the Rentech-SilvaGas gasification process at the McNeil power station in Burlington, VT. Website:  HYPERLINK "http://www.rentechinc.com" www.rentechinc.com SG Biofuels Based in: 132 N. El Camino Real, Suite O, Encinitas, CA 92024 Year Founded: 2006 Annual revenues 2009 (projected), 2008, 2007 N/A Type of technology: SG Biofuels is utilizing breeding and genetics to drive further improvements to the yield and profitability of Jatropha as a non-edible, plant-based feedstock. Type(s) of fuel produced: SG Biofuels produces crude oil from Jatropha that can be used for a variety of bio-based materials including biodiesel and feedstock substitutes for the petrochemical and jet fuel industries. Major investors. Privately funded 3 top milestones for 2008-09. Assembled a world-class leadership and scientific team including executive management, energy, biotechnology and agribusiness veterans, as well as three members of the National Academy of Sciences. Launched Genetic Resource Center including the largest library of Jatropha genetic material in the world (more than 6,000 accessions) Identified several cold tolerant strains capable of thriving at temperatures and altitudes not previously considered possible. 3 major milestone goals for 2010-11. Bring first commercial product to market. Sequence the Jatropha genome. Drive cost per gallon of Jatropha oil to less than $1.00. Business model: SG Biofuels business model is to produce superior, high-yielding and profitable strains of Jatropha and use this advanced genetic material to generate revenue through seed and plantation development. Fuel cost: Currently at $1.50 per gallon. We expect to drive that cost to below $1.00 per gallon in the next two to three years. Competitive edge: Our competitive advantage is three-fold: a world-class leadership team, leading-edge science and genetics and expertise in agronomy and plantation management. SG Biofuels has assembled the worlds largest, most diverse library of Jatropha genetic material and teamed with leading plant geneticists to develop improved varieties. The company has a large trait pipeline including yield improvements, cold-tolerance and decreased agronomic inputs. Further developments will include climate adaptations that will expand the opportunities for Jatropha to include non-tropical climates around the world. Through its Genetic Resource Center, SG Biofuels has already identified several strains of Jatropha capable of thriving in colder, higher elevations. Development stage: Research & Development Website URL  HYPERLINK "http://www.sgbiofuels.com" www.sgbiofuels.com Shell Oil Based in: Netherlands Business: Oil & gas exploration, production, refining and marketing; biofuels investments in Codexis, Cellana, Virent and Iogen. Model: Owner-operator, investor. Past milestones: In Scotland, the Glenturret Distillery in Perthshire announced that it would convert waste CO2 to biodiesel by growing algae as a biofuel feedstock. Scottish Bioenergy confirmed in a BBC report that it had constructed the first pilot-scale algae bioreactor at Perthshire in cooperation with the distillery, Shell, Edrington Group and the Scottish Environmental Technology Network. In Canada, a Shell station in Ottawa became the first in the country to serve cars with cellulosic ethanol, offering a 10 percent blend of gasoline and wheat straw ethanol manufactured at a demonstration-scale cellulosic ethanol plan jointly owned by Shell and Iogen. Last October, Iogen announced that it had commenced shipments of a 47,000 gallon cellulosic ethanol order from venture partner Royal Dutch Shell. The companies first partnered in cellulosic ethanol in 2002 when Shell invested in Iogen. Shell subsequently increased its ownership stake in Iogen's technology to 50 percent in 2007. The company recently expanded an agreement with Codexis to accelerate the arrival of next-gen fuels. Future milestones: Commercialization of one or more of the companys investments in cellulosic ethanol, algae biofuels or renewable diesel. Metrics: Shell OIl CEO Jeroen van der Veer said that biofuels will account for 7-10 percent of global fuel supply "over the next few decades". It expects to market "commercial volumes" of next generation biofuels within the next 5-10 years. Solix Biofuels Based in: Colorado Business: Algal fuel developer Model: Owner-operator Past milestones: Solix Biofuels completed its $16.8 million Series A capital funding that added Shanghai Alliance Investment to its group. Proceeds will be used to finance construction and commencement of operations at the company's Coyote Gulch Demonstration Facility, which will be operational by late summer 2009. I2BF Venture Capital, Bohemian Investments, Southern Ute Alternative Energy LLC, Valero Energy Corp., and Infield Capital also invested in this round. Solix Biofuels said that it has commenced production of algal oil at its Coyote Gulch Demonstration Facility, and said that full-scale commercial operation would commence later this summer. The Coyote Gulch farm is on two acres near Durango, on Southern Ute tribal land. Solix said that it expects to reach a production rate of 3,000 gallons per acre per year by later this year at the facility. Dr. Bryan Willson, co-founder and Chief Technology Officer of Solix, has been named to the Scientific American 10: Guiding Science for Humanity", as "the 10 most influential people in the nation who have demonstrated outstanding commitment to assuring that the benefits of new technologies and knowledge will better humanity." Future milestones: Development of commercial-scale photobioreactor facility. Metrics: The company says it is currently at around 2500 gallons per acre, and said that the company is on track to achieve cost parity with $80 oil in 3-4 years. The company has said that it can produce algae-based fuel on a scaled-up basis at this point, for $32.81 per gallon. Solix, which has a photobioreactor-based technology, said that it can reduce the cost to $5.50 per gallon by eliminating external power consumed in drying its algae and powering the bioreactors, and reducing it further to $3.50 per gallon through sales of algae-based byproducts including proteins. Sriya Innovations Based in: 1831 West Oak Parkway, Suite B Marietta, GA 30062 Year Founded: 2003 Annual Revenues: N/A Technology: NanoCatalyticSolvoThermal (NCST) Fuel type: Low cost C5 and C6 sugars for cellulosic ethanol and other advanced biofuels production Biochemicals including biomass derived ethylene glycol, furfural and low molecular weight lignin (current) Next generation of products currently under development include phenols, vanillin, xylitol and terephthalic acid Major investors: Kleiner Perkins: $22M invested in Series A and B 3 top milestones for 2008-09: Proved NCST platform at bench scale Proved NCST platform at pilot scale: 100 kg/d (dry basis) Designed and built process development unit (PDU) and confirmed process at 3 tonnes/d (dry basis) 3 major milestone goals for 2010-11: Develop engineering scale data at PDU scale, confirm process economics, and establish product markets/customers Design and build demonstration scale plant: 80 tonnes/d (dry basis) Design and bring commercial plant online: 320 tonnes/d (dry basis) Business model: Licensing for liquid transportation fuels, Owner/operator for value added chemicals Fuel cost: Sriya can produce sugars for <$1/gallon on equivalent ethanol basis. These sugars have been tested by leading universities and ethanol providers who have concluded they ferment quickly with no inhibition problems. Competitive edge: Reaction time in seconds: Six (6) orders of magnitude faster than enzymatic process Flexible feedstock inputs: Sriya technology is biomass agnostic and works for corn stover, corn cobs, wheat straw, rice straw, soft and hardwoods "Dial a Product": Tunable to produce both high volume fuels and high value chemicals like sugars, ethanol, MEG, vanillin, xylitol, furfural, HMF, phenolics No Consumables: Does not use acids, bases, enzymes or external solvents Economical: On a distributed products basis, sugars can be produced for as little as $.04/lb on an operating basis. Extremely fast reaction times (seconds/minutes for biomass deconstruction and cellulose hydrolysis) enable very low capital expenses. Fast fermentation times: Our crude sugars ferment quickly without inhibition problems using current commercial conditions Lignin to phenols & vanillin: Converts low value lignin into high value bio-products Development stage: Pilot facility opening early November 2009; Demonstration facility planned for late 2010; Commercial for 2011 Website URL: www.sriyanova.com SRS Engineering Corporation Based in: 25843 Jefferson Avenue. Murrieta, CA 92562 Year Founded: 1985 Annual Revenues: 2009 - $20M (projected) 2008 $5,554,590.00 2007 - $4,393,749.00 Technology: Transesterification Glycerin Purification High FFA Pretreatment Biodiesel Distillation Methanol Recovery Biodiesel Washing Turnkey Biodiesel Plants Fuel type: Biodiesel Major investors: The owners Past milestones (08-09): SRS received 4 contracts to engineer and manufacture biodiesel plants. Starting up two biodiesel plants simultaneously Expanded our manufacturing facility and our capabilities in the United States and in India. 3 major milestone goals (2010-11) SRS plans to expand its research and development in the field of biodiesel Explore next generation fuels including renewable diesel Market our glycerin purification systems to the existing biodiesel plants to increase their profits. Business model: Corporation Competitive edge: SRS Engineering is uniquely positioned to handle its small and large projects with the same level of detail. Our biodiesel plants have the lowest energy consumption and because of the fact that we employ the best automation technologies available, our plants require minimal human intervention thus reducing overhead and the customers bottom line. Our company has an extensive engineering background backed up by Fortune 500 companies and recognizable companies worldwide. Alliances and Partnerships: SRS is expanding its marketing efforts to Argentina and other South American countries with possible partnerships on the horizon Website: www.srsbiodiesel.com Storm Fisher Biogas Based in: Ontario, Canada( 2008-09 ranking: Unranked( ( Business: Biomethane, converted to grid-connected electricity, via anaerobic digestion. Model: Build, own, operate Past milestones: 1. Have 5 projects; over 20 MW in late stage development with construction starting in 2009?2. Built a pipeline of 37 MW of new projects?3. Raised significant private equity financing Future milestones: 1. All 5 late-stage projects operational or in construction( 2. Construction on first facility may commence Fall 09 3. Post-revenue in 2010 Metrics: Diverting organic by-products from landfills and land application reduces methane emissions by a factor of tendeep fryer oil can generate about 60 times as much biogas as cow manure for any given quantity. StormFisher quotable quotes: "Competitive edge is integration of existing technologies with a focus on commercial contracts." "Our experience with producers of organic by-products is that disposal can be a significant cost centre, with tipping and transportation fees ranging in many cases above $100 per tonne. Under agreements with us, companies can often reduce these costs as these by-products are beneficially used rather than dumped, and our plants are being built in or near major food processing clusters." SunOpta BioProcess Based in: Ontario, Canada Business: SunOpta BioProcess pecializes in the design, construction and optimization ofbiomass conversion equipment and facilities. Over 30 years experience delivering biomass solutions to producecellulosic ethanol, cellulosic butanol, xylitol and dietary fiber for human consumption. Raw materials include wheat straw, corn stover, grasses, oat hulls and wood chips. SunOptas says that its technology is the only continuous, industrially proven process in the world that can pretreat biomass at the temperatures and pressuresrequired for subsequent enzymatic hydrolysisfor the production of fermentable sugars. Model: The investment, ownership and management of cellulosic ethanol facilities by SunOpta and with strategic partners. Technology License and Sale or Lease to Third Parties. Incremental Cellulosic Ethanol Production at Existing Starch Ethanol Plants Past milestones: Biomass to Cattle Feed 1973 Xylitol from Oat Hulls and Birch Fines 1983 Cellulosic Butanol Straw/Wood Waste for Road Fuel 1985 Cellulosic Ethanol R&D Poplar/P&P Waste Streams 1987 Hydro Mulch from Orchard Waste 1990 Published Hall Mark Paper Fractionation of PopulustremuloidesCellulosic Ethanol 1991 Cellulose, Hemicellulose, Lignin Extraction 1992 Ammonia Pretreatment of Cellulose 1993 Rye Grass Straw to Liner Board 1995 Dietary Fiber for human consumption from Oat Hulls 1999 Cellulosic Ethanol (CelEtOH) from Straw 2003 PR of China CRAC Corn Stover CelEtOH Operational 2006 Spain Abengoa Salamanca Wheat Straw Start Spring2007 Celunol Jennings Louisiana Bagasse Start May 2007 In 2007, SunOpta closed the previously announced private placement for a minority position in SunOpta BioProcess Inc., formerly the SunOpta BioProcess Group. In aggregate, SunOpta raised US$30 million before related placement costs through the issuance of non-dividend bearing, convertible preferred shares of SunOpta BioProcess Inc. Future milestones: SunOpta BioProcess intends to build and own or co-own commercial scale cellulosic ethanol production facilities worldwide through relationships such as the previously announced Joint Venture with GreenField Ethanol, Canadas largest ethanol producer. SynGest Based in: 310 Green Street, San Francisco, CA 94133 Year Founded: 2008 Annual Revenues: None. First production facility is in the process of being constructed. Operations are expected to begin in Fall 2011. First full year of operations will be 2012. Technology: Oxy-blown Gasification of biomass Fuel type: Initially we will produce BioAmmonia (anhydrous ammonia) to be used as fuel and nitrogen fertilizer. Ammonia is the best hydrogen carrier and is an effective fuel in ICEs as well as alkaline fuels cells or can be used as a hydrogen store for other hydrogen applications. Later, with our efficient syngas production (only CO and H2), we can use a variety of catalytic back end to produce a wide variety of other fuels that range from Di-Methyl Ether (DME) to ethanol. It turns out that nitrogen fertilizer is the most valuable product that can be made from biomass. Major investors: Self funded to date. Recent investments include: $3M cash assistance package from the Iowa Department of Economic Development, Pending $2.5M Cash Assistance from the Iowa Power Fund and a substantial cash investment from the Heartland Coop (West Des Moines). Past milestones (08-09): 1. Company formation 2. Patents applied for 3. Complete team assembled: Executive team, engineering, distribution, EPC, investors 4. Site selection, environmental review, permits, zoning. 5. Major endorsements from Governor Culver, Guthrie County Board of Supervisors, Senators Harkin (IA) and Grassley (IA), Ben Nelson (NE), Congressmen Boswell (IA) and King (IA), USDA Secretary Vilsack. 3 major milestone goals (2010-11) 1. Start of construction in Spring 2010 2. Build out of biomass (corn cob) supply chain 3. Start of full scale operations late Fall 2011 Business model: Owner/Operator. Typical project finance model. Fuel cost: $300/T for the production of anhydrous ammonia. Competitive edge: Low cost of production from using local waste product (corn cobs) and reduced storage and transport costs. Superior technology for conversion of biomass to syngas. Alliances and Partnerships: Heartland Coop will be our distribution partner for 100% of our production Technology consultants/sub-contractors Alion Sciences and Particulate Solid Research are assisting with gasifier optimization. Weitz Construction is out EPC partner. Development stage: In the process of building our first commercial scale demonstration facility just outside Menlo, IA to process 130,000 tons of biomass annually into 50,000 tons of BioAmmonia (anhydrous ammonia). Website: HYPERLINK "http://www.SynGest.com/"www.SynGest.com Targeted Growth Based in: 2815 Eastlake Avenue East, Suite 300, Seattle, WA 98102 Year Founded: 1998 Annual Revenues: Targeted Growth does not disclose revenue Technology: Targeted Growth is a bioscience company, developing technologies that both increase seed size and yield in major crops. It has also developed a line of dedicated energy crops, including camelina and sugarcorn, as well as a non-agricultural feedstock cyanobacteria algae for biomass. Fuel type: Targeted Growth products can be used for ethanol, biodiesel, and biojet. Major investors: Alliance Bernstein, Capricorn Investment Group, GrowthWorks, Skoll Foundation and Victoria Park Capital. 3 top milestones for 2008-09 Targeted Growth has made significant strides in the past two years in developing dedicated, non-food crop plants for use in biofuels. 1. In January 2009 Targeted Growth provided camelina that powered a Japan Airlines test flight of a Boeing 747-300 aircraft. The test flight, which took place in Tokyo, Japan, was powered by biojet fuel derived from camelina (84%), jatropha (under 16%) and algae (under 1%) oil, refined by UOP Honeywell. The results of the flight conclusively confirmed the second-generation biofuels operational performance capabilities and potential commercial viability. 2. In July 2009 Targeted Growth announced it has developed a way to increase the lipid content of blue-green algae (cyanobacteria) by approximately 400 percent. This discovery dramatically increases the oil yield per acre, decreases the cost of algae production and helps algae-based biofuels become price-competitive with petroleum. 3. In early August 2009 Targeted Growth provided camelina used to power the Boeing U-787 unlimited hydroplane at the annual Chevrolet Cup at Seattles Seafair weekend. The U-787 boat became the worlds first to be powered by 100 percent sustainable biofuel and ran the fastest qualifying lap of the weekend at 153.6 miles per hour, six seconds faster than the previous years run on petroleum-based fuel. 9. 3 major milestone goals for 2010-11 In 2010-11, the company will continue to advance its algae program as well as expand acreage of camelina across the United States. Business model: Targeted Growth has a diversified approach to generating revenue. Including partnership,ks commercial product development and commercial licensing. Fuel cost: N/A Competitive edge: Strong Science & Partnerships: Targeted Growth has been researching and developing dedicated energy crops for more than 10 years. Founded in 1999, the company has a history of strong science and has strategic partnerships with leading researchers and agribusinesses around the world. The combination of sound science and strong partnerships allows the company to continue to develop technologies that both increase seed size and yield in energy crops. Alliances and Partnerships: Targeted Growth maintains a joint venture with Green Earth Fuels, a vertically integrated biodiesel energy company, creating the company Sustainable Oils, Inc. Sustainable Oils is a producer and marketer of renewable, environmentally clean, and high value bio- based biofuels. Development stage: Targeted Growth is a decade-old bioscience company that derives revenue from commercial sales, partnerships and licensing. Website URL:  HYPERLINK "http://www.targetedgrowth.com" www.targetedgrowth.com Terrabon Inc. Based in: - 20333 State Highway 249, Suite 200, Houston, TX 77070 Year Founded - 1995 Annual revenues 2009 (projected) - $2,000,000 2008 - $0 2007 - $0 Type of technology Anaerobic mixed culture fermentation followed by chemical conversion of fermentation products into biofuels and bio-chemicals. Fuel Tye: Depending on chemical pathway chosen, we can produce mixed primary alcohols (a mix of ethanol, propanol, butanol, pentanol, hexanol and heptanol), mixed secondary alcohols (a mix of isopropanol, 2-butanol, 3-pentanol, 2-pentanol, etc), green gasoline, green diesel and green jet fuel. At the moment we are concentrating on producing green gasoline. Major investors - Valero Energy and Waste Management 3 top milestones for 2008-2009 - Constructed and operated 5-ton per day semi-works plant using sweet sorghum as feedstock; Produced ketones, secondary alcohols and gasoline fromfermentation broth producedin semi-works plant; and Started construction of 300 gal/day pilot plant for gasoline and jet fuel production. 3 major milestone goals for 2010-2011 - Operation of 300-gal/day pilot plant for green gasoline production using products from fermentation of various feedstock, including municipal solid waste and various non-food energy crops; Constructand operate 55-ton per day integrated bio-refinery to produce 1.3 million-gal/yearof green gasoline using post-sorted municipal solid waste (MSW) and primary sewage sludge as feedstock; and Construct five (5) 220-ton per day MSW bio-refineries (each with production capacity of 5.5 million gal/year) optimally sited between Waste Managements MSW operations and Valero refineries. Business model: Joint venture arrangements with Valero/Waste Management, and licensing arrangements for larger facilities (300 to 500-ton per day) using agricultural and forest residue, food scraps and non-food energy crops as feedstock. Fuel cost: - $2.00 per gallon for 220-ton per day MSW plant (breakeven cash conversion costs of $1.15 per gallon). Competitive edge: Low Capital and Operating Costs. Low capital costs for small scale 220-ton per day facilities ($7.50 per annual gallon) - because the mixed culture fermentation does not require sterile vessels or piles to enable efficient fermentation) and low operating costs ($2.00 per gallon because the process can use a broad array of cellulosic feedstock, including MSW typically destined for a landfill where the attendant costs of collection and transporting are already incurred, effectively making its embedded energy value cost-free); Low-Cost, Readily Available Feedstock. Feedstock advantage in using sustainable, low cost and readily available feedstock in the form of MSW, primary sewage sludge and urban wood residues as well as set the stage to extend this platform into agriculture waste streams such as corn stover and energy crops such as sorghum; High Energy Recovery. In the case of MSW, over 72% of the feedstocks energy content survives the conversion processes, even when the undigested residue is not used as a heat source for the process, while mass is reduced by over 60%, enabling low cost product transportation and significantly lower amounts of residual waste destined for landfills; Reduced GHG Emissions. In the case of MSW, a reduction of 187% in lifecycle emissions compared to emissions from traditional transportation fuel pathways can be realized (consisting of 20% due to lower project emissions and 167% due to avoided landfill methane emissions); and Infrastructure Efficiencies from the Hub and Spoke Configuration. The hub and spoke concept of siting the technology such that its biochemical conversion facilities are located near the sources of feedstock (MSW or other non-food organic waste) with intermediate products (e.g., ketones) transported to central refinery facilities, reducing inefficient biomass transportation and increasing economies of scale for the central refinery facilities. Distribution, research, marketing or production partnerships or alliances Extensive research partnership with Texas A&M University dating back to 1995; Feedstock management and supply partnership with Waste Management; and Product refining and distribution partnership with Valero. Development stage: Demo-scale to commercial-scale applications. Website URL www.terrabon.com ThermoChem Recovery International (TRI) Based in: 3700 Koppers Street, Suite 405, Baltimore, MD, 21227 Year Founded: 1996 Technology:: Steam reforming gasification Fuel type: TRIs high-quality, medium-BTU syngas can be converted into a wide range of downstream biofuel and biochemical products. Since 2003, a TRI gasifier has been in commercial-scale operation at Norampacs Trenton (Ontario) containerboard mill, gasifying black liquor (solid biomass equivalent: 500 dry tons per day). Currently, TRI is the gasification technology provider for two separate DOE-funded biorefinery projects which will convert TRI syngas to Fischer-Tropsch waxes and diesel for market sale, and provide tailgas to offset natural gas use in the lime kiln. One of these projects, NewPage Corporation, converts 500 dry tons per day of woody biomass feedstock, and the other, Flambeau River BioFuels, converts 1,000 dry tons per day. Both are integrated with existing paper mills and benefit from tight thermal integration of the biorefinery and host facility, utilizing tail gas, steam and hot water streams for maximum economic advantage. Major investors: The Abell Foundation, Inc., a leading Maryland foundation established in 1953, which makes investments in breakthrough clean energy technology companies based in Maryland. Past milestones (08-09): Award of NewPage Corporations DOE Biorefinery grant, with TRI as main technology provider Award of Flambeau River BioFuels DOE Biorefinery grant, with TRI as main technology provider Successful launch of state-of-the-art proprietary 4 dry ton per day Process Demonstration Unit (PDU) in Durham, North Carolina 3 major milestone goals (2010-11) Ground-breaking on NewPage project Ground-breaking on Flambeau River BioFuels project Project close on RDF-to-fuels project Business model: TRI licenses its proprietary gasification technology and provides specialized equipment and engineering services to integrate biorefineries with energy hosts like pulp and paper mills. Fuel cost: This varies by feedstock, size and configuration of plant, ability to fully utilize and monetize energy by-products (tail gas, steam, hot water, etc.) and type of end products, but TRI has very competitive operational costs across a range of different project/product scenarios. Competitive edge: TRIs main competitive advantages come from three key attributes of its proprietary technology: 1.) an ability to successfully gasify a wide range of feedstocks (woody biomass, agricultural residues, Refuse Derived Fuel, lignite, subbituminous coal, etc.) into a consistent and reliable medium-calorific (300-350 BTU/dscf) syngas; 2.) a proven ability to dial in the ideal hydrogen to carbon monoxide (H2:CO) ratio required by the specific downstream GTL conversion process; and 3.) a highly-scalable steam reformer vessel design such that project sizes from 500 2,000 dry tons per day can be accommodated by a single gasification system. TRI can handle a wide range of different feedstocks coming in, and can reliably supply syngas capable of producing a wide range of different energy products. Alliances and Partnerships: TRI has established research, marketing and technology partnerships across a wide range of entities and resources to most widely commercialize our proprietary technologies. We treat these relationships as business confidential until specific project-related announcements can be made. Development stage: TRI has been commercial on black liquor, a liquid biomass, since 2003 and is currently at demo scale on solid biomass, entering into commercial scale. Website: HYPERLINK "http://www.tri-inc.net"www.tri-inc.net TMO Renewables Based in: UK 2008-09 ranking: Unranked Business: Licensor of a cellulosic microbe that produces up to 15 percent more ethanol than traditional fermentation technology, and reduces energy inputs in the fermentation and distillation process. Model: Licensing, including a royalty on production of additional gallons of ethanol ("the TMO gallons"). Investors include: Jupiter Asset Management, Noble Group, RAB Capital, Presnow Limited, Diverso Management, Libra Advisors Past milestones: 1. Development of a secure, scalable application of technology, following the scientific breakthrough of discovering the microbe. 2. Commissioning of the company's demonstration plant in Surrey, UK, used for customer demonstrations and feedstock testing. 3. Raising $18 million in 2009's nefarious capital markets, funds that will be used to take TMO's technology to the US.( ( Future milestones: 1. TMO is now in the commercialization phase, with "customer, customer, customer" as the focus. Numerous collaborations with ethanol project owners and developers will need to be converted into commercial customer relationships. Look for TMO to secure its first customer this year. 2. Look also for an independent report this year confirming that with use of TMO Renewables technology, starch gallons can qualify as advanced biofuels under the terms of the Renewable Fuel Standard based on direct GHG emissions. 3. Look for increased feedstock flexibility. Metrics: TMO's system costs $47-$60 million to implement, although payback comes within three years according to CEO Hamish Curran. The investment will provide up to 15 Mgy in additional fuel production at a traditional 100 Mgy ethanol plant.( ( Hamish Curran (CEO) quotable quotes: "Here in the UK, after what was known as the Gallagher Review, the government reversed the biofuels mandate on the basis of the Searchinger paper, which wasn't a proof, it was a hypothesis, even if an interesting one. When properly analyzed, I think indirect land use change (ILUC) will go away." "When my chairman asked me why our pricing allowed customers to achieve a 30 percent internal rate of return, he rightly asked if we might possibly take a larger share of the pie. My background is in oil & gas, and I told him that when you go into the boardroom to compete for capital, the projects that are approved in this industry will need to be in the 25-30 percent bracket to win that competition, to make it interesting." YSI Life Sciences Based in: Ohio Business: YSI Life Sciences is apart of YSI Incoporated. Founded in 1948 and formerly known as Yellow Springs Instrument Company, YSI develops and manufactures scientific instruments, sensors and systems that serve a variety of scientific, environmental, and industrial markets worldwide. The YSI method uses immobilized enzyme electrodes to measure the glucose and xylose present. 13 L of sample are automatically aspirated and delivered to the electrode chamber. Two electrodes develop signals proportional to the glucose and xylose present. Results are printed, displayed and stored after about 30 seconds. The system automatically clears sample from the electrode chamber and the next sample is ready to run. Turn around time is typically under two minutes. Model: Service provider Past milestones: In 2009, launched xylose sensor, an enzyme electrodemembrane for use on the existing YSI 2700 SELECT and YSI 7100 MBS. Xylose and glucose sensors are configured in the same electrode chamber allowing simultaneous measurement of these sugars in one-minute. Metrics: The YSI enzyme electrode technology provides accurate one-minute results with minimal sample preparation. Website: www.ysilifesciences.com Other eligible companies A2BE Carbon Capture Acitera AE Biofuels Ago Industrie Agragen Agrenco Airbus Algepower Allard Alpine Energy AM Oil Anellotech Aquafuel Research Ardent Energy Arkansas Soy Energy Arrow Energy Athens Biodiesel AXI Badger State Ethanol BAE Systems Bayer/Athenix Bay State Biofuels Beacon Energy Bentley Motors Big River United Energy Biocardel Vermont Biocom BioCube Bioenergia Bioenergy Systems Bioexchange Biogasol Biojet Biomass Secure Power Biopetrol Bioprocess Algae Biopur Biotericity Boeing Bronze Oak BS Bioj Buffalo Biodiesel Canadian Bioenergy Carbio AgraFuel Carbon Science Catalin Central Farmers Cooperative Cellana Cello Energy Cereal Process Technologies Chemetha Chevron China Sun Biochem Circle Biodiesel Coastal Biodiesel Companhia di Buzi Continental Foods Coshocton Ethanol Cosmo Oil Covanta CPC Taiwan Dalby Ethanol Eastern Sugar Easy Energy EcoEnergy China EcoFasa Eco Global Bio Oils Eco Plus EcoSystem Emami Biofuels Encore Energy Systems Endress + Hauser Ensus Environmental Power Envergent Technologies EverCat Fuels Equatorial Biofuel/Agriterra Evodos Evogene Evolution Fuels ExxonMobil FCL First In Spec First United Ethanol FL Biofuels Fort Dodge Ethanol Four Rivers Bioenergy Freedom Biofuels GAEC Galp Energia Galten GC Biofuels Gea Biofuels General Atomics General Motors Genomatica Gleinol Global Biofuels Global Energy Holdings Gold Star Biofuels Gold Star Farms Great Plaims The Camelina Company Green Plains Renewable Energy Greenfield Ethanol Green Gold Greenhunter Green Star Products Guardian Energy Gulf Alternative Energy Gulf Hydrocarbon Partners Hawkeye Renewables Healy  CONTACT _Con-3FFC95D4124D \c \s \l Biodiesel Magazine Helius Energy Highwater Ethanol HyPower HR Biopetroleum Husker Ag Husky Energy IBI ICM Imperium Renewables Inbicon InterAgro Inland Empire Oilseeds Innovation Fuels Inventure Chemical Jaimca Broliers Jatoil JR Camelina Seed Kaaima Bio AgriTech Kai Bioenergy Kent Seatech Kilimanjaro Biofuels Kinder Morgan Lignol Live Fuels Lightning Hybrids Linde Group Maple Energy Martek MDB Energy Methes Metso Mettler Toledo Mississippi Investment Petroleum Monsanto Myriant MXI Neste Oil New Generation Biofuels N-Viro Organic Bioenergy OPX Biotechnologies Orion Ethanol Otter Tail Oxem Biodiesel Pacific Bio-Fields Pacific Ethanol PEMEX Perdue PetroCard PetroChem Carless PetroSUn Pinnacle Energy Polish Mills Powers Energy of America Prairie Pride Promethius Carbon Pro Natura Proteus QD Sciences Quest Air R-3 Energy Reclaim Resources REII Renewable Fuel Renewable World Energies Renewafuel Rex Stores Rocky Mountain Sustainable Ronn Vision Biofuels Royal Cosun SAAB Saline Green San Carlos Sanimax Schroeder Industries Scipio Biofuels Shree Ranuka Sugars SK Chemicals Solid Energy Soy Mor Biodiesel Springboard Statoil Stellar Wind Bioenergy Sudanese Kenama Sugars Suncor Energy Sunset Ridge Algae Tata Terra Grain Fuels TerraSol Terra Sonics Tharaldson Energy Toyota Tellurian Biodiesel Tolero Trillium Uniol United Utilities US Biodiesel Utica Energy Valcent Vale Vega Biofuels Veredium Vivergo Fuels WAL-Mart Waste Management Western Biofuels White Energy Ze-Gen Zymetis 50 Hottest Companies in Bioenergy 2009-10 Selector Book  PAGE 1 24P2­Ճp_J___7$hFsh0J5B*OJQJph(hFsh0J5B*CJ$OJQJph!hGah0JB*OJQJph%hFsh0JB*CJ OJQJph(hFsh0J5B*CJ OJQJph(hFh0J5B*CJ0OJQJph(hGah0J5B*CJ0OJQJph%hGah0JB*CJ0OJQJph$hGah0J5B*OJQJph-jhGah0J5B*OJQJUph(234P>? 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Courier New;Wingdings;|i0Batang  hsƻs 'IM $j]5 !4d%nN `b1Jim LaneJim Lanel                           ! " # $ % & ' ( ) * + , - . / 0 1 2 3 4 5 6 7 8 9 : ; < = > ? @A B C D E F G H I J K L M N O P Q R S T U V W X Y Z [ \ ] ^ _ ` a b c de f g h i j k  Oh+'0H  ( 4 @ LX`hpx'1 Jim LaneNormal Jim Lane3Microsoft Word 11.5.5@G@J.[@-_e@.de'IG PICT b HHb bHHPbb                I N.k!2Vs Jreeb+w5eoY{fo7g,!>2Lo26mcX BFW5Jk26cXBF.k[rYnebj(oXnjn{njlsYwVjkjrebLg, >&I'  *j!!**.+rYwe^*eb+eb]`fl]j(Ye^ jIfmebmg,!' &I !"(!2l *j **:n!nYweb*e^ ]`j]`faf]reanefg,a&I* !2l &)* .+*J.K`jk]j(afebMea]`fK]nlYnkfebmebog,6*j.k[6B:_W"(&)kz>>[V.k6m_W"(&)_W*jR2lJwnjnjj{xnjoXjkfK]`sYjIf(orffl{nJfL{eab g{JRRo{wwo{$^Vg9kZ{g9so{kZZwsg9Vo{cs{kZo{g9kZkZVkZkZZso{^o{{Zg9g9Zwg,VR-kVNs5F1-kR-kg99^Ns-kJR-kNs^)JJR)JB=5o{=B%)F1^9B9F1951Bg91=1F1NskZww                  =o{kZskZccwkZkZww^g9wvg92Vo{Zso{ZZssg9Z^so{g9g9kZckZo{sg9kZkZssg9g9VVNskZso{ssg9kZsscg9kZg9sywg9ZsRR^g9ccRwNs^^o{s^g9ZVkZc^VZZRwNsR=RcV^g9RwVZRwZ^sZ{^g9o{o{+ o{kZskZskZso{o{kZskZskZ"g9ZVg9so{g9g9-VkZZsZswVVkZZskZg9Zs           IkZg9^kZ^^kZg9ZkZR^{^cF1^'JR^g9so{VNsJR^o{o{Vcg9F1^o{o{Ro{o{so{Ns^o{g9Z^F1JRo{o{g9o{g9NskZe+^^JRF1JRcBF1wF1JRJRcBsF1B{^^BsF1BsJRwNsJRNs^JRJR=^^Ns^Ns^=JR  -^g9^wkZo{g9^m/Zg9kZsw^kZkZwZkZg9kZo{kZswso{g9g9kZckZo{sg9kZg9sckZckZJRkZ^ssg9o{sg9kZwZkRVZV{V^ZZVZVZ^sV{^g9ZVkZc^VZZ{VkZZ^F1ZVRwNs{c^VZZV!g9o{^o{^ ^wEckZsswso{g9g9kZg9g9kZssg9kZwZo{sZkZso{g9kZg9?ZRwV{^g9ZRwVZZVc^cZ^g9VZNs{                                        wwg^R^ZkZNskZRZRZcNs^cVRVcVVg9^R cRkZ^VNs^kZF1ZZ^kZ         _ ՜.+,D՜.+, hp  'Lane & Associates M 1QCost-Competitive Biorefinery Solution: Feedstocks and end products can be optimQThe BioForming process is a practical biorefinery alternative that can speed the Title Headings 8@ _PID_HLINKS'ATJ&*http://www.tri-inc.net%http://www.targetedgrowth.com)Shttp://www.SynGest.com/ http://www.sgbiofuels.com&http://www.rentechinc.com[&http://cts.businesswire.com/ct/CT?id=smartlink&div=lcajedejafi&url=http%3A%2F%2Fen.wikipedia.org%2Fwiki%2FFischer%E2%80%93Tropsch_process&esheet=6061599&lan=en_US&anchor=Fischer-Tropsch&index=1+2http://www.bigteclabs.com/MP!http://www.remfuelbioenergy.com/_T%http://www.purevisiontechnology.com/G~http://www.pricebiostock.comE,{http://www.planktonpower.com/9xhttp://www.phycal.comyPuhttp://www.joulebio.comYrhttp://www.glycosbio.com$_ohttp://www.geosynfuels.com/X~l"http://www.fulcrum-bioenergy.com/7Si http://www.dynamicfuelsllc.com/pZfhttp://www.dsm.com%0CDyadic$"chttp://www.contechfab.com/XZ`)http://www.continentalbiorefineries.com/2m]http://www.cometborefining.com)rZhttp://www.codexis.com>:Whttp://www.bp.com/biofuelsL@T!http://www.bluemarbleenergy.net/pQhttp://www.biomcn.eu/>.Nhttp://www.biofuelbox.com/DBKhttp://www.avantium.com/ Hhttp://www.1hourflex.com/I,Ehttp://www.originoil.com/_:Bhttp://www.sekab.com/uZ?http://www.verenium.com&Q<http://www.bladeenergy.com/S49http://www.ceres.net/_T6!http://www.oppenheimerfunds.com/OA3http://www.gimv.com/#0http://www.st1.eu/wH-http://www.klenergycorp.com<=*http://www.cobaltbiofuels.com/< '0http://zeachem.com/press/pressrelease022309.php>$0http://zeachem.com/press/pressrelease010809.phpB_!http://www.ddce.com/5Qhttp://www.mascoma.com/"Qhttp://www.marathonoil.com/"3http://www.gm.com/.Zhttp://www.pinnacleven.com/MLhttp://www.kpcb.com/?W http://www.generalcatalyst.com/XC http://www.atlasventure.com/%4 http://www.khoslaventures.com/P]!http://www.flagshipventures.com/^_http://www.amyrisbrasil.com/41http://www.anyris.com/8KBD09new  HotFuelsx  HotTechnologies  !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~      !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz{|}~                           ! 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