ĐĎॹá>ţ˙ ŕâţ˙˙˙ÚŰÜÝŢß˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙˙ěĽÁq` řżIcbjbjqPqP >::"[&˙˙˙˙˙˙¤FFFFFFFZÉÉÉ8:ÉlŚÍ|ZUBö.ĐN|Ô"žÔžÔžÔyŐ ;â?ćÔAÖAÖAÖAÖAÖAÖA$KDhłF úAF8őyŐyŐ8ő8őúAFFžÔžÔŰBŢţŢţŢţ8őÄFžÔFžÔÔAŢţ8őÔAŢţŢţ2h/FFH5žÔ"Đ őPŔÎÉüřě„3.@A”%B0UB˛3–SGčű’SG\H5H5@SGFˆ6¸ Cč cěňŢţUď\ąń‡CčCčCčúAúAzţdCčCčCčUB8ő8ő8ő8őZZZäâ>éÄßZZZ>éZZZFFFFFF˙˙˙˙  HARVEY MUDD COLLEGE PHYSICS DEPARTMENT August 9, 2013 LIST OF DEMONSTRATIONS USING THE PIRA SCHEME The PIRA Demonstration Classification Scheme  The goal of the PIRA Demonstration Classification Scheme is to create a logically organized and universally inclusive taxonomy giving a unique number to every lecture demonstration. The structure of the classification system is as follows:   Example: 1C10.25 – Glider on Air Track  1Area(mechanics)CTopic(motion in one dimensions)10Concept(velocity).25Demonstration(Glider on Air Track) PIRA CLASSIFICATION SCHEME Mechanics HYPERLINK \l "Measurement1A" \t "_top"1A - Measurement HYPERLINK \l "Motion1C" \t "_top"1C - Motion in One Dimension HYPERLINK \l "Motion1D" \t "_top"1D - Motion in Two Dimensions HYPERLINK \l "Motion1E" \t "_top"1E - Relative Motion HYPERLINK \l "Newton1F" \t "_top"1F - Newton's First Law HYPERLINK \l "Newton1G" \t "_top"1G - Newton's Second Law HYPERLINK \l "Newton1H" \t "_top"1H - Newton's Third Law HYPERLINK \l "Newton1J" \t "_top"1J - Statics of Rigid Bodies HYPERLINK \l "Newton1K" \t "_top"1K - Applications of Newton's Laws HYPERLINK \l "Gravity1L" \t "_top"1L - Gravity HYPERLINK \l "Work1M" \t "_top"1M - Work and Energy HYPERLINK \l "Momentum1N" \t "_top"1N - Linear Momentum and Collisions HYPERLINK \l "Rotational1Q" \t "_top"1Q - Rotational Dynamics HYPERLINK \l "Matter1R" \t "_top"1R - Properties of Matter 1T –  HYPERLINK \l "TheoreticalPhysics1T" Theoretical Physics Fluid Mechanics HYPERLINK \l "Surface2A" \t "_top"2A - Surface Tension HYPERLINK \l "Fluids2B" \t "_top"2B - Statics of Fluids HYPERLINK \l "Dynamics2C" \t "_top"2C - Dynamics of Fluids Oscillations and Waves HYPERLINK \l "Oscillations3A" \t "_top"3A - Oscillations HYPERLINK \l "Wave3B" \t "_top"3B - Wave Motion HYPERLINK \l "Acoustics3C" \t "_top"3C - Acoustics HYPERLINK \l "Instruments3D" \t "_top"3D - Instruments  HYPERLINK \l "Sound3E" 3E – Sound Reproduction Thermodynamics HYPERLINK \l "Thermal4A" \t "_top"4A - Thermal Properties of Matter HYPERLINK \l "Heat4B" \t "_top"4B - Heat and the First Law HYPERLINK \l "Change4C" \t "_top"4C - Change of State HYPERLINK \l "Kinetic4D" \t "_top"4D - Kinetic Theory HYPERLINK \l "Gas4E" \t "_top"4E - Gas Law HYPERLINK \l "Entropy4F" \t "_top"4F - Entropy and the Second Law Electricity and Magnetism HYPERLINK \l "Electro5A" \t "_top"5A - Electrostatics HYPERLINK \l "Electric5B" \t "_top"5B - Electric Fields and Potential HYPERLINK \l "Capacitance5C" \t "_top"5C - Capacitance HYPERLINK \l "Resistance5D" \t "_top"5D - Resistance HYPERLINK \l "Electromotive5E" \t "_top"5E - Electromotive Force and Current HYPERLINK \l "DC5F" \t "_top"5F - DC Circuits HYPERLINK \l "Magnetic5G" \t "_top"5G - Magnetic Materials HYPERLINK \l "Magnetic5H" \t "_top"5H - Magnetic Fields and Forces HYPERLINK \l "Inductance5J" \t "_top"5J - Inductance HYPERLINK \l "Electromagnetic5K" \t "_top"5K - Electromagnetic Induction HYPERLINK \l "AC5L" \t "_top"5L - AC Circuits HYPERLINK \l "Semicond5M" \t "_top"5M - Semiconductors and Tubes HYPERLINK \l "Electromagnetic5N" \t "_top"5N - Electromagnetic Radiation Optics HYPERLINK \l "GeomOptics6A" \t "_top"6A - Geometrical Optics HYPERLINK \l "Photometry6B" \t "_top"6B - Photometry HYPERLINK \l "Diffraction6C" \t "_top"6C - Diffraction HYPERLINK \l "Interference6D" \t "_top"6D - Interference HYPERLINK \l "Color6F" \t "_top"6F - Color HYPERLINK \l "Polarization6H" \t "_top"6H - Polarization HYPERLINK \l "Eye6J" \t "_top"6J -The Eye HYPERLINK \l "Optics6Q" \t "_top"6Q - Modern Optics Modern Physics HYPERLINK \l "Quantum7A" \t "_top"7A - Quantum Effects HYPERLINK \l "Atomic7B" \t "_top"7B - Atomic Physics HYPERLINK \l "Nuclear7D" \t "_top"7D - Nuclear Physics HYPERLINK \l "Elementary7E" \t "_top"7E - Elementary Particles HYPERLINK \l "Relativity7F" \t "_top"7F - Relativity Astronomy and Astrophysics HYPERLINK \l "Astronomy8A" \t "_top"8A - Planetary Astronomy HYPERLINK \l "Astronomy8B" \t "_top"8B - Stellar Astronomy HYPERLINK \l "Cosmology8C" \t "_top"8C - Cosmology Electronics HYPERLINK \l "Electronics9B" \t "_top"9B - Electronics AVAILABLE DEMOS ARE IN BOLD Demo with pictures, indicated by (*) and demos with videos, indicated by( #) are available at the following site:  HYPERLINK "http://www.hmc.edu/academicsclinicresearch/academicdepartments/physics/kiosk1/demos.html" http://www.hmc.edu/academicsclinicresearch/academicdepartments/physics/kiosk1/demos.html I. MECHANICS Measurement – 1A00.00 Basic Units – 1A10.00 Error and Accuracy – 1A20.00 a. Catch a Meter Stick* – 1A20.60 (Jacobs B122-285) CATCH A METER STICK – 1A20. 60 - Hold a meter stick up and have a student volunteer hold his fingers beside the 50cm point. -Ask the student to grab the meter stick the instant he sees you drop it. -Drop the meter stick. -After the student catches the meter stick, measure the distance from the 50cm mark to the point where he caught the meter stick. -Convert distance to reaction time: t = square root of (2d/g). Coordinate Systems – 1A30.00 Vectors -1A40.00 Math Topics – 1A50.00 Scaling – 1A60.00 Motion In One Dimension – 1C00.00 1. Velocity - 1C10.00 a. Glider on Air track* – 1C10.25 (Demo Room) GLIDER ON AIR TRACK 1C10.25 - To demonstrate velocity in one dimension set a glider in motion on an air track Falling Ball and Paper – 1C20.16 b. Falling Ball and Paper – 1C 20.16 (Jacobs B122 – 281) FALLING BALL AND PAPER – 1C10.25 - On a pan balance, balance a flat sheet of paper with a ping-pong ball so that they have equal masses. - Drop them simultaneously and watch the ping-pong ball land well-ahead of the fluttering paper. - Gently crumple the paper to match the ping-pong ball. - Drop them together and this time they land together. - Now squish the paper into a ball half is size, and drop both balls again. - The smaller paper ball lands first. 2. Uniform Acceleration – 1C20.00 a. Inclined Air Track* – 1C20.30 (Demo Room) INCLINED AIR TRACK – 1C20.30 - Air track will be leveled. Place aluminum blocks under single leg of air track to create desired incline. - Turn on the air supply. - To find the average velocity by using two photo gates. . 3. Measuring g – 1C30.00 Motion In Two Dimensions – 1D00.00 1. Displacement in Two Dimensions – 1D10.00 2. Velocity, Position, and Acceleration – 1D15.00 a. High Road Low Road*# - 1D15.20 (Demo Room) ;Small Version Jacobs B122-276) HIGH ROAD LOW ROAD – 1D15.20 - First ask the class to predict which ball will win - Both tracks are the same angle, except for the transition segments. 4. Central Forces – 1D50.00 a. Centripetal Force Demo*# – 1D50.20 (Jacobs B122) CENTRIPETAL FORCE DEMO – 1D50.20 - A long string is freely hanging through a small pipe, used as a handle. - Tie a bob on one end of a string and hang weights on the other end. - The bob and the string are lighter than the hanging weight. - Twirl the bob overhead while the twirling action suspends the mass. - Observe the suspended mass pulling the bob inward due to the tension in the string. a. Pail of Water* – 1D50.40 (Jacobs B122-374) PAIL OF WATER – 1D50.40 - Swing pail in a large vertical circle b. Rolling Chain*# - 1D50.70 (Demo Room) ROLLING CHAIN – 1D50.70 - The chain is mounted on the motor. - Start the motor by turning on the switch - Abruptly push the chain away from the motor - Chain will roll to a distance before it collapses. 5. Deformation by Central Forces – 1D52.00 a. Flattening the Earth* – 1D52.10 (Jacobs B122-283) FLATTENING THE EARTH – 1D52.10 - Hang the Hoberman Sphere. - Rotate the sphere and, like the Earth, it becomes oblate. - Its equator moves outward and its poles draw together. - Central forces push the sphere’s center outwards, narrowing its radius. a. Water Parabola*# – 1D52.20 (Jacobs B122-279) WATER PARABOLA – 1D52.20 - A rectangular flat glass container mounted on ball bearings is filled with colored water and spun. - As the setup rotates, one can observe the parabolic curve formed by the water's surface. 6. Centrifugal Escape – 1D55.00 a. Broken Ring on Overhead Projector* – 1D55.10 (Jacobs B122-286) BROKEN RING (OHP) – 1D55.10 - Place the ring near the edge of the table so that the ball will roll parallel to the edge. - Roll a steel ball around the inside of the ring. - Hold the ring securely while the ball is rolling around the ring. - Have the class vote which way the ball will roll when it reached the gap. 7. Projectile Motion - 1D60.00 a. Funnel Cart Trajectory*# – 1D60.10 (Demo Room) FUNNEL CART TRAJECTORY – 1D60.10 - A ball fired vertically from a cart moving horizontally falls back into the cart. b. Simultaneous Fall* – 1D60.20 (Jacobs B122-279) SIMULTANEOUS FALL – 1D60.20 - A Spring loaded device drops one ball and projects the other horizontally. - Listen for the sound of balls striking the floor. Only one click should be heard. c. The Monkey and the Hunter*# – 1D60.30 (Demo Room) THE MONKEY AND THE HUNTER – 1D60.32 - Aim the cannon at the monkey when monkey is held up high. - When the ball leaves the cannon, the monkey should drop. - The ball will hit the monkey since they fall at the same rate. d. Projectile Launcher (Pasco)* - 1D60.70 (Keck B127) PROJECTILE LAUNCHER – PASCO – 1D60.70 - Shoot balls at different angles. Relative Motion – 1E00.00 1. Moving Reference Frames – 1E10.00 2. Rotating reference frames – 1E20.00 3. Coriolis Effect – 1E30.00 Newton’s First Law – 1F00.00 1. Measuring Inertia - 1F10.00 2. Inertia of Rest – 1F20.00 a. Inertial Block* – 1F 20.10 (Jacobs B122 – 371) INERTIAL BLOCK – 1F20.10 - Place the block near the top of the pipe. - Tap the pipe on the floor or table top and watch the block move down the pipe. - Hold the PVC pipe near the top with one hand and tap the top of the pipe with a mallet. - Watch the block move back up the pipe. b. Inertial Wooden Disks*# – 1F 20.11 (Jacobs B122 – 264) INERTIAL WOODEN DISKS - 1F20.11 - Stack wooden nickels. - With a flat plastic ruler whip the ruler back and forth, knocking the disks out from the bottom of the pile. - The stack remains in place while the bottom disk is knocked out by the ruler. c. Smash Your Hand* – 1F 20.20 (Jacobs B122 – 352) SMASH YOUR HAND – 1F20.20 - Place a lead brick on a hand or on a piece of fruit. - Hammer the brick, give it a good whack. - The person doesn’t howl with pain. 3. Inertia of Motion – 1F30.00 a. Persistence of Motion – Cart on Air Track* – 1F30.10 (Demo Room) PERSISTENCE OF MOTION (AIR TRACK) – 1F30.10 - Air track is leveled. Turn on the air supply. - Push cart and allow it to bounce back and forth long the track. - Nearly all energy loss occurs during the collisions at the ends of the track. Newton’s Second Law - 1G00.00 1. Force, Mass and Acceleration – 1G10.00 2. Accelerated Reference Frames – 1G20.00 a. Weightlessness in Free Fall – Mass in Cup on Pole – 1G20.38 (Jacobs B122 - 284) WEIGHLESSNESS IN FREE FALL - MASS IN CUP ON– 1G20.38 - A long broomstick has a cup attached to the end. - Inside the cup are a ball and a weak spring. - When the ball hangs out of the cup the spring is too weak to pull it back in. - When the stick is raised up in the air and released gravity is instantly switched off. - In the absence of gravity (freefall) the weak spring has the ability to pull the all back into the cup. This apparatus is also called Einstein’s Toy. It was designed by Eric Rogers of Princeton and presented to Einstein on his 76th birthday. b. Dropped Slinky* – 1G20.45 (Jacobs B122-163) DROPPED SLINKY – 1G20.45 - Hold a slinky so some of it extends downward, and then drop it to show the contraction 3. Complex Systems – 1G30.00 Newton’s Third Law – 1H00.00 1. Action and Reaction- 1H10.00 a. Push Me Pull You Carts* – 1H10.10 (Jacobs B 122- 231A ) PUSH ME PULL YOU CARTS – 1H10.10 - Hold Ask two students to stand on two different carts and hold a rope between them. - Have only one student pull on the rope. - Observe that they both move toward each other. - Have the other student pull on the rope, observe the same effect. - Use a stick instead for pushing. - Both carts move away from each other as only one student pushes on the stick. 2. Recoil – 1H11.00 Statics and Rigid Bodies – 1J00.00 1. Finding Center of Gravity – 1J10.00 a. Map of State* - 1J10.10 (Jacobs B122-370) MAP OF STATE – 1J10.10 - Hang map of your state on a peg through the desired hole. - Hand a plumb bobbin front - Mark plump line with marker. - Repeat with other holes. - Where the lines cross is the center of gravity. b. Fingers Find CG* - 1J10.20 (Jacobs B122 171) FINGERS FIND CG – 1J10.20 - Hold a 2m meter-stick horizontally, with one finger under each end. - As the fingers slowly draw together, the meter stick slides so as to remain balanced. - Try different starting points or add a small mass to one end of the stick. 2. Exceeding Center of Gravity – 1J11.00 a. Tower of Lire* – 1J11.20 (Keck B127) TOWER OF LIRE – 1J11.20 - Place wooden or metal blocks on top of each other with each progressive block hanging out farther than the last. b. Double Cone*# – 1J11.50 (Jacobs B122-286) DOUBLE CONE – 1J11.15 - Place the double cone on the lower end of the “U” and it will roll uphill. 3. Stable, Unstable and Neutral Equilibrium – 1J20.00 a. Nine Nails on One*# – 1J20.25 (Jacobs B122-371) NINE NAILS ON ONE – 1J20.25 -Balance the set of 9 nails on one b. Center of Gravity Paradox Stick* -1J20.26 (Demo Room & Jacobs B122-274) CENTER OF GRAVITY PARADOX STICK – 1J20.26 -This center of gravity paradox shows that a lower center of mass doesn’t always increase stability. - Balance the stick w/ attached mass - The weight farther away works better due to its moment of inertia. 4. Resolution of Forces – 1J30.00 5. Static Torque – 1J40.00 a. Torque Beam* – 1J40.22 (Jacobs B122-285 &Demo Room) TORQUE BEAM – 1J40.22 - Use combinations of masses and distances to show torques in equilibrium -Distances are in integer multiples: r, 2r, 3r, 4r. -Masses are equal Applications of Newton’s Laws – 1K00.00 1. Dynamic Torque – 1K10.00 a. Walking the Spool* – 1K10.30 (Demo Room) WALKING THE SPOOL – 1K10.30 - Pull the rope that is wound around the spool. - The angle between the rope and the table determines the direction the spool will roll. - At some angle, the spool will not roll, but slide when you pull it. 2. Friction – 1K20.00 a. Friction Blocks – Surface Materials*# – 1K20.10 (Demo Room) FRICTION BLOCKS – SURFACE MATERIAL – 1K20.10 - Measure static friction by noting the scale reading just before the block slides. - Measure sliding friction by pulling the block at a constant speed. - Change the surface materials and note the different frictions. b. Static vs. Sliding Friction*# – 1K20.30 (Demo Room) STATIC VS SLIDING FRICTION – 1K20.30 - Pull on a block with a spring scale until just before the block moves. - Note the reading on the spring scale. - Pull the block slowly across the table. - Compare the spring scale readings. c. Inclined Plane – Angle of Response*# - 1K20.35 (Demo Room) INCLINED PLANE – 1K20.35 - Set and empty box on the inclining plane - Increase the angle until it slides. - Add weights to the box and repeat the experiment. - This shows that the coefficient of friction does not depend upon the mass of the object. d. Friction and Cord Around a Cylinder*# - 1K20.71 (Jacobs B122) FRINCTION AND CORD AROUND A CYLINDER – 1K20.71 - Suspend two different masses with a cord around a fixed cylinder so that the masses are in equilibrium - Add a mass on one side and observe the cord sliding. - Wrap the cord around the cylinder once and see that the cord does not slide. - Repeat adding more masses and wrapping the cord around the cylinder multiple times. - The result is exponential. 3. Pressure – 1K30.00 a. Bed of Nails and Balloon*# – 1K30.15 (Jacobs B122-369) BED OF NAILS AND BALLOON – 1K30.15 - A balloon is placed on a bed of 25 nails. - 500 g masses are placed on a board which rests on the balloon. - The 25 nail bed is replaced with a single nail and the procedure is repeated. Gravity – 1L00.00 1. Universal Gravitational constant – 1L10.00 a. Cavendish Balance* – 1L10.30 (Keck B127) CAVANDISH BALANCE – 1L10.30 - Initially the balance is in equilibrium with the two large lead balls in one extreme position up against the face of the balance. - At the start of the lecture the balls are moved to the other extreme position. - The suspension goes into oscillation. - By the end of the period the motion of the suspension approaches a new equilibrium position brought about by the change in the gravitational force on the dumbbells. 2. Orbits – 1L20.00 a. Eliptic Motion in a Funnel*# – 1L20.14 (Jacobs B 111) ELIPTIC MOTION IN A FUNNEL – 1L20.14 - Release a ball inside a large funnel. - Observe the ball as it proceeds toward the middle of the funnel. - Start the ball at different initial positions and observe the wide variety of orbits. Work and Energy – 1M00.00 1. Work – 1M10.10 2. Simple Machines – 1M20.00 3. Non-Conservative Forces – 1M30.00 4. Conservation of Energy – 1M40.00 a. Loop the Loop*# – 1M40.20 (Jacobs B122-146) LOOP THE LOOP – 1M40.20 - Release the ball near the top of the track. - The energy loss makes the minimum height necessary to complete the loop significantly higher than the calculated value. a. Ring Jumping with Two Large Stainless Steel Beads*# – 1M40.30 (Jacobs B122-146) RING JUMPING WITH TWO LARGE STAINLESS STEEL BEADS – 1M40.30 - A ring hangs from a thread and two stainless steel beads slide on it without friction. - The beads are released simultaneously from the top of the ring and slide down opposite sides. - Observe the ring rising if the mass of each bead is greater than 3/2 of the mass of the ring. b. Yo-Yo* – 1M40.50 (Jacobs B122-280) YO-YO – 1M40.50 - Release the yo-yo straight downward holding the cord firmly. - It will have enough kinetic energy to return itself to about one-third the original height at release. c. Hopper Popper* – 1M40.91 (Jacobs B122- 280) HOPPER POPPER – 1M40.91 - Turn ‘hopper popper’ inside out. - Hold the cut edge of the ball facing the floor and drop it. - It will bounce several times higher than the original height. (Energy is stored in the ball when it is forced to turn wrong side out and is released when it hits the floor). 5. Mechanical Power – 1M50.00 Linear Momentum and Collisions – 1N00.00 1. Impulse and Thrust – 1N10.00 2. Conservation of Linear Momentum – 1N20.00 3. Mass and Momentum Transfer – 1N21.00 4. Rockets – 1N22.00 5. Collisions in One Dimension – 1N30.00 a. Collision with 5 Hanging Balls*# – 1N30.10 (Jacobs B122-011) COLLISION WITH 5 HANGING BALLS - 1N30.10 - Observe the effects of displacing different numbers of balls. - Try one ball first, then two and so on up to five balls at once. b. Newton’s Cradle*# – 1N30.20 (Jacobs B122-011) NEWTON’S CRADLE – 1N30.20 - Raise a ball away from the others and release it- It collides with its neighbor. - The momentum of the ball is transferred through the system. - The ball on the other end reacts accordingly. - Repeat the process with two balls, or three, or four. - This demonstrates conservation of momentum in a collision involving several bodies. c. Large Ball and Small Ball Drop*# – 1N30.60 (Jacobs B122-273 & 275) LARGE BALL AND SMALL BALL DROP – 1N30.60 - Place a small ball on top of a big ball and drop from a height of about 4 feet d. Velocity Amplifier using Stacked Disks*# – 1N30.62 (Demo Room) VELOCITY AMPLIFIER USING STACKED DISKS – 1N30.62 - Four discs (1 5/8", 3 1/8", 5", and 8") are placed on top of each other such that they stand vertically. - The four discs are also confined to the vertical plane. - Raising and releasing two discs will cause the smallest disc to bounce a few inches. - Raising three will cause the smallest disc to bounce out of the apparatus a few inches. - Raising and releasing all four will cause the smallest disc to fly many feet into the air. e. Double Air Glider Bounce on an Air Track* – 1N30.65 DOUBLE AIR GLIDER BOUNCE – 1N30.65 (Demo Room) - Let two air carts accelerate down an inclined air track - Vary the mass of the first cart and measure the rebound height of the smaller cart Collision in Two Dimensions – 1N40.00 a. Super Ball Bounces *#– 1N40.60 (Jacobs B122-280) SUPER BALL BOUNCES – 1N40.60 - A super ball is bounced under a flat surface, such as a table. - The super ball then bounces back. - Bounce the ball at a 45 degree angle to the ground for good results. Rotational Dynamics – 1Q00-00 PASCO’S Complete Rotational System provides a range of experiments in centripetal force, angular momentum and rotational motion.* (Demo Room) 1. Moment of Inertia – 1Q10.00 a. Inertia Wands*# – 1Q10.10 (Demo Room) INERTIA WANDS – 1Q10.10 - Twirl equal mass wands, one with the mass at the ends and the other with the mass at the middle. - The wand with the mass concentrated in the middle rotates much easier than the wand with the mass concentrated at the ends. b. Ring and Disk Race (rolling on incline)* – 1Q10.30 (Demo Room) RING, DISK AND SPHERE RACE – 1Q10.30 - Each item has the same diameter. - After leveling the track from side release them all at the same time and see which one gets to the bottom first. - To release all objects at the same time, place a meter stick against the supports. With objects resting against the meter stick, remove the stick quickly with an upward motion. c. Rolling vs. Sliding* – 1Q10.31 (Demo Room) ROLLING VS. SLIDING – 1Q10.31 - Two identical looking masses, one with rollers at the bottom are released on an inclined plane. - See which one gets to the bottom first. d. Racing Soup Cans* #– 1Q10.50 (Demo Room) RACING SOUP CANS – 1Q10.50 - Two unopened soup cans are rolled down a ramp. - One is dense soup (cream of mushroom) and the other one is lighter (beef broth) - See which one reaches the bottom first. 2. Rotational Energy – 1Q20.00 a. Complete Rotation Demonstration* (Pasco) – 1Q20.10 PASCO’S COMPLETE ROTATIONAL SYSTEM – 1Q20.10 (Demo Room) - The system provides a range of experiments in centripetal force, angular momentum and rotational motion. b. Driven Torsion Oscillation- Indian Driller* – 1Q20.21 DRIVEN TORSION OSCILLATION – Indian Driller – 1Q20.21 (Demo Room) -Indian Driller to show rotational energy. 3. Transfer of Angular Momentum – 1Q30.00 a. Passing the Wheel*# – 1Q30.10 (Demo Room) PASSING THE WHEEL – 1Q30.10 - Tip the spinning tire half way and hand it to a student on a turntable - The student tips it another half way and hands it back. - Repeat until the spinning student is turning so fast for the hand off. - Add or subtract from the angular momentum depending on which way the wheel is tipped. b. Driven Torsion Oscillation- Indian Driller* – 1Q30.12 (Demo Room) DRIVEN TORSIOAN OSCILLATION – INDIAN DRILLER – 1Q30.12 -Indian Driller to show transfer of angular momentum. 4. Conservation of Angular Momentum – 1Q40.00 a. Rotating Stool with Weights*# – 1Q40.10 (Demo Room) ROTATING STOOL WITH WEIGHTS – 1Q40.10 - Start rotating with dumbbells close to your body. Or else be careful to begin with a slow spin. - Watch the change in spin the masses are moved further away. b. Rotating Hoberman Sphere* – 1Q40.22 (Jacobs B122 - 283) ROTATING HOBERMAN SPHERE – 1Q40.22 - Expand the Hoberman sphere by removing the small clip at the bottom. - Give the sphere a slight push to make it spin slowly. - As it is spinning, pull on the bottom pull ring and watch the angular velocity change. - Do not pull hard enough to collapse the sphere completely. This damages the pulley system. c. Pulling on the Whirligig* – 1Q40.25 (Jacobs B122 - 274) PULLING ON THE WHIRLIGIG – 1Q40.25 - Attach balls to either ends of a string that passes through a hollow tube so you can set one ball twirling and pull on the other ball to change the radius. - Spin the ball around while holding the hollow tub. - Move the lower ball up and down to change the radius of the circle. d. Rotating Stool and the Bicycle Wheel*#– 1Q40.30 (Demo Room) ROTATING STOOL AND BICYCLE WEEL – 1Q40.30 - Tip a spinning wheel sitting on a rotating platform. - Tip the wheel in the opposite direction to spin to change the direction on the spinning platform. e. Suitcase Demo*#– 1Q40.50 (Jacobs B122 - 033) SUITCASE DEMO – 1Q40.50 -A large fly-wheel is mounted in a suitcase. -Start the fly-wheel a couple of minutes before the demo. -Have a student carry the suitcase around the corner. f. Mystery Space Ship – Defies Gravity *#– 1Q40.55 (Jacobs B122 - 264) MYSTERY SPACE SHIP – DEFIES GRAVITY – 1Q40.55 - Plastic spaceship toy with encased gyroscope with a holder and a crank on top. - When cranked it performs numerous spinning tricks, balancing on its side, on center post, or attached to a string. g. Hero’s Engine* – 1Q40.80 (Jacobs B122 - 285) HERO’S ENGINE – 1Q40.80 - Put an amount of liquid nitrogen in the bottle and tighten the bottle to the cap and PVC pipe assembly. - Hold the other end of the PVC firmly and lower the bottom of the bottle into a container (Nalgene beaker) 1/3 full of water. - As soon as the bottom of the bottle touches the water the liquid nitrogen will begin to boil and pressurize. - The nitrogen gas escaping will cause the bottle to run at a high rate of speed. 5. Gyros – 1Q50.00 a. Precessing Gyro* – 1Q50.50 (Demo Room & Small Gyros Jacobs B122-280) PRECESSING GYRO – 1Q50.50 - A gyroscope with a counterweight is used to show the fundamental precession equation. 6. Rotational Stability – 1Q60.00 a. Lazy Suzan with Spring Scales* - Sparks – 1Q60.01 (Demo Room) LAZY SUZAN – 1Q60.01 -Lazy Suzan to show rotational stability. b. Stacking Wooden Blocks* - Sparks – 1Q60.02 (Demo Room) STACKING WOODEN BLOCKS – 1Q60.02 - Stacking wooden blocks to show rotational stability. c. Tippe Top*# – 1Q60.30 (Jacobs B122 -265) TIPPE TOP – 1Q60.30 -Hold the stem of the top and spin it on its round bottom. -The top spins and goes round in larger and larger circles until its stem touches the surface on which it spins. -The top then flips over and continues spinning on the stem. Properties of Matter – 1R00.00 1. Hooke’s Law a. Stretching a Spring* – 1R10.10 (Jacobs B122 - 168) STRETCHING A SPRING – 1R10.10 - A 50 gram mass hanger hangs on a spring - Begin with 50 grams on the hanger. This brings the spring into its linear range. - Mark the position of the bottom of the hanger on a meter stick positioned next to it with a clamp. - Add 100 gram masses to the hanger marking the positions after each addition. - Compare the end positions of masses that are multiples, such as double or triple. 2. Tensile and Compressive Stress – 1R20.00 3. Shear stress – 1R30.00 a. Shear Strain with a Foam Block – 1R30.20 (Jacobs B122 ) SHEAR STRAIN WITH A FOAM BLOCK – 1R30.20 - Deform a large foam block. 4. Coefficient of Restitution – 1R40.00 a. Happy and Sad Balls* – 1R40.30 (Jacobs B122 - 166) HAPPY AND SAD BALLS – 1R40.30 - Drop bounce and no bounce balls. - Measure the height the bouncing ball is dropped from and the height it bounces to and calculate the coefficient of restitution. - The sad ball will not bounce as it is made from energy absorbing material. 5. Crystal Structure – 1R50.00 Theoretical Physics – 1T00.00 Geodesics – 1T10.00 a. Geodesics* – 1T10.10 (Jacobs B122 - 278) GEODESICS -1T10.10 - This demo shows how a curve is the shortest distance between two points in a curved space. - Two points on a globe are connected by a straight line and another one curved going through the arctic. - Both distances are measured. - The distance connected through the arctic is shorter. II. FLUID MECHANICS Surface Tension – 2A00.00 1. Force of Surface Tension – 2A10.00 a. Floating Metals* – 2A10.20 (Jacobs B122 - 022) FLOATING METALS – 2A10.20 - Place the needle on a bit of tissue and place on the surface of fresh water. - Sink the tissue with a stick, leaving the needle floating. - Add a little soap to sink the needle. b. Surface Tension Bottle*# – 2A10.60 (Jacobs B122 - 280) SURFACE TENSION BOTTLE – 2A10.60 - A flask has a screw top cork with a small hole. - Insert a slender object through the hole to show that a hole indeed exists, - Fill the flask with water and insert the cork and invert it. - No water will exit through the hole. 2. Minimal Surface – 2A15.00 a. Soap Film* – 2A15.10 (Jacobs B122 - 022) SOAP FILM – 2A15.10 - Dip a frame with a loop of thread in soap. Pop the film in the center of the thread by blowing on it. The formula for the solution is: ˝ gallon (1890 ml) distilled water, 1/3 cup (80 ml) Dawn, 1Tablespoon (7.5 ml) Glycerin. 3. Capillary Action – 2A20.00 4. Surface Tension Propulsion – 2A30.00 Statics of Fluids – 2B00.00 1. Static Pressure – 2B20.00 a. Pressure vs. Dept*# – 2B20.15 (Jacobs B122 - 264) PRESSURE VS. DEPT – 2B20.15 - A plastic tube has a hole at the bottom and a cover at the top. - A drainage container is provided to catch the stream of water. - Fill the tube with water. When the cover is removed a jet of water falls in the drainage container - Observe how the pressure of the water is dependent on the height of the water column above it. 2. Atmospheric Pressure – 2B30.00 a. Crush the Soda Can*# – 2B30.10 (Jacobs B122 - 022) CRUSH THE SODA CAN – 2B30.10 - Put a small amount of water in a soda can. - Partially fill the bowl with water. - Bring water in the can to a boil. - Using tongs, flip the can over into bowl of cold water. - Watch the can immediately collapse. b. Magdeburg Vacuum Plates* – 2B30.25 (Jacobs B122 - 273) MAGDEBURG VACUUM PLATES – 2B30.25 - Use a hand pump to evacuate the Magdeburg plates. - About 140 pounds of force are needed to separate them. c. Egg in Bottle – 2B30.47 (Jacobs B122 ) EGG IN BOTTLE - 2B30.47 - Put 4 lit matches into a milk bottle. - Put a hard boiled egg on the mouth of the bottle. - The egg is pushed into the bottle by atmospheric pressure. d. Rubber Sheet Lifting a Stool*# – 2B30.50 (Jacobs B122 - 264 ) RUBBER SHEET LIFTING A STOOL- 2B30.50 - Place a square thin rubber sheet with a handle on a stool. - The stool is lifted by pulling up on the handle. e. Vacuum Cannon -2B30.70 (Demo Room & Jacobs B122 – 149 and 281) VACUUM CANNON – 2B30.70 - Place the vacuum cannon on the table and clamp the pop can holder directly in front of the cannon muzzle. - Place a 40mm Ping-Pond ball into the muzzle and roll it all the way down to the stop provided by the vacuum inlet. - Place 3-M packing tape onto each end of the cannon taking care to insure that the tape is flat so that it does not have any air leaks. - Pump the air out of the cannon with the vacuum pump. - When desired vacuum is reached, shut the valve on the cannon and turn off the vacuum pump. - Using a sharp object, puncture the tape at the rear end of the cannon. - The Ping-Pong ball will be driven out the other end of the cannon by the inrushing air and will puncture several soda cans. f. Spark Gap Alcohol Popper* – 2B30.71 (Jacobs B122 - 370) SPARK GAP ALCOHOL POPPER – 2B30.71 - Add 3 drops of alcohol into the canister and close the lid. Avoid putting too many drops of alcohol - Aim the cap away from any people or fragile objects and pull the trigger. 3. Measuring Pressure – 2B35.00 4. Density and Buoyancy – 2B40.00 a. Weigh Submerged Object* – 2B40.10 (Jacobs B122 -168 &176A) WEIGH SUBMERGED OBJECT – 2B40.10 - Weigh a 1 Kg. object in air and then in water. 5. Siphons, Fountains, Pumps – 2B60.00 Dynamics of Fluids – 2C00.00 1. Flow Rate – 2C10.00 2. Forces in Moving Fluids – 2C20.00 a. Bernoulli’s Tube*# – 2C20.10 (Jacobs B122 - 286) BERNOULLI’S TUBE – 2C20.10 - Blow across the top of the transparent vertical tube with Styrofoam plug. - Observe how the Styrofoam plug rises demonstrating how the Bernoulli effect causes the pressure in moving air to become less than atmospheric. b. Wind Bags* – 2C20.22 (Jacobs B122 - 280) WIND BAGS – 2C20.22 - Blow into a long tubular plastic bag known as a “Wind Bag.” - If the bag is placed right over the mouth, it will barely inflate when blown into. - If the bag is held a few inches away from the mouth and blown into, it will inflate a much greater amount, as air in the region is pulled into the stream of air entering the bag. c. Bernoulli’s Funny Car*#– 2C20.35 (Jacobs B122 - 281) BERNOULLI’S FUNNY CAR 2C20.35 - Demonstrate Bernoulli’s principle by supporting a Styrofoam ball in a stream air. - Put Styrofoam ball on smokestack. - Move switch to GO position. d. Singing Boogle Tube*# – 2C20.36 (Jacobs B122 - 275) SINGING BOOGLE TUBE- 2C20.36 - Hold at one end and swing the tube to hear the not. Adjust the speed of the tube to obtain higher or lower pitch. 3. Viscosity – 2C30.00 a. Falling Bodies Air Resistance*# – 2C30.65 (Jacobs B122) FALLING BODIES AIR RESISTANCE – 2C30.65 - A flat piece of paper is dropped and the time to fall a specified distance is noted. - The paper is then crumpled and dropped again. - Coffee filters can be used to fall without tumbling and by stacking them mass is added without increasing the effective surface area. 4. Turbulent and Streamline flow – 2C40.00 5. Vortices – 2C50.00 a. Smoke Ring* – 2C50.10 (Jacobs B122 - 275) SMOKE RING USING ZERO BLASTER – 2C50.10 - Fill tank with super Zero Fog Fluid - Gently hold in power lever until Light in fog chamber indicates Zero Blaster is on, wait 5 seconds. - Pull pump lever to fill fog chamber with fog. - Pull firing trigger back until plunger is released. - To make large fog rings push the Zero Blaster forward, about 12 inches, with a smooth constant speed. b. Vortex in a Beaker*# – 2C50.31 (Jacobs B122 - 264) VORTEX IN A BEAKER – 2C50.31 - Fill the beaker with water. - Place a magnetic stirrer in the water. - Put the beaker on a stirring plate. - Observe the formation of vortex in the beaker. 6. Non Newtonian Fluids – 2C60.00 III. OSCILLATIONS AND WAVES OSCILLATIONS *– 3A00.00 1. Pendula – 3A10.00 a. Simple Pendulum* – 3A10.10 (Demo Room & Jacobs B122) SIMPLE PENDULUM – 3A10.10 - The length of the pendulum is adjustable. - A timer can be used to measure the period. 2. Physical Pendula – 3A15.00 a. Sweet Spot*– 3A15.50 (Demo Room & Jacobs B122-286) SWEET SPOT– 3A15.50 - A baseball bat or a metal pipe hangs from a pin that can slide along the horizontal support rods. - The forked end of the pivoting arrow straddles the pin. - Start with the arrow straight up. When the bat is struck above or below the sweet spot the arrow indicates the direction the end of the handle moves. - The arrow remains stationary only when the bat is struck at the marked sweet spot. 3. Springs and Oscillators – 3A20.00 a. Mass on a Spring* – 3A20.10 (Demo Room & Jacobs B122 – 168 & 178A) MASS ON A SPRING – 3A20.10 - Place a hooked mass on a spring. - Pull down and release to start simple harmonic motion. - If desired, time the oscillation and calculate the frequency. - Change to a different mass in order to change the frequency. b. Air Track Glider and Spring* – 3A20.30 (Demo Room) AIR TRACK GLIDER AND SPRING – 3A20.30 - An air track cart oscillates on a stiff spring. - The cart oscillates. Change the period by adding weights on the cart. c. Air Track Glider Between Springs* – 3A20.35 (Demo Room) AIR TRACK GLIDER BETWEEN SPRINGS – 3A20.35 - An air track cart is between two light extension springs. - Add mass to the glider to change the period. 4. Simple Harmonic Motion – 3A40.00 a. Arrow on the Wheel*# – 3A40.30 (Demo Room) ARROW ON THE WHEEL – 3A40.30 - An arrow is mounted on a rotating wheel or a timer. - The arrow’s shadow is projected onto a wall. 5. Damped Oscillations – 3A50.00 6. Driven Mechanical Resonance – 3A60.00 a. Tacoma Narrows Film/ Video – 3A60.10 TACOMA NARROWS FIL M – 3A60.10 - 8 sec. clips can be found online at  HYPERLINK "http://www.stkate.edu/physics/phys111/curric/tacomabr.html" http://www.stkate.edu/physics/phys111/curric/tacomabr.html b. Driven Cart Between Springs# – 3A60.24 (Demo Room) DRIVEN CART BETWEEN SPRINGSODS – 3A60.54 - A PASCO cart is placed between two long springs. - The cart is driven by a variable speed motor. - Eddy current damping is used also. c. Resonance in Rods* – 3A60.51 (Jacobs B122 - 284) RESONANCE IN RODS – 3A60.51 - Three pairs of spring-steel wires are affixed to a horizontal rod. - A brightly colored mass is affixed to the end of each wire. - When any wire is “plucked”, its equal-length counterpart of the opposite side of the device oscillates with large excursions while the other four wires and weights remain relatively motionless. 7. Coupled Oscillations – 3A70.00 a. Coupled Pendula* – 3A70.20 (Demo Room & Jacobs B122) COUPLED PENDULA - 3A70.20 - Two pendula hang from a flexible metal frame. Start one pendulum oscillating. The pendula will pass the energy back and forth. A third pendulum can be added. b. Coupled Oscillation with Tennis Balls*# – 3A70.21 (Jacobs B122- 260) COUPLED OSCILLATION WITH TENNIS BALLS - 3A70.21 - Two pendula made of tennis balls and flexible metal trips connected with a rubber band. - Start one pendulum oscillating. - The pendula will pass the energy back and forth. c. Spring Coupled Pendula*# – 3A70.25 (Demo Room & Jacobs B122) SPRING COUPLED PENDULA – 3A70.25 - Two simple pendula are connected only by a very light spring. - Displace one pendulum perpendicular to the spring and observe the coupling that occurs. 8. Normal Modes – 3A75.00 9. Lissajous Figures – 3A80.00 9. Non-Linear Systems – 3A95.00 a. Chaos Pendulum (Math Dept. Demo) – 3A95.50 (Math Department) Video at: http://www.math.hmc.edu/~jacobsen/demolab/doublependulum.html CHAOS PENDULUM – 3A95.50 - Two identical pendulums are released at what appear to be the same point. - As the release points of the pendulums are slightly different, the behavior of the pendulums will soon diverge noticeably from each other. WAVE MOTION – 3B00.00 1. Transverse Pulses and Waves – 3B10.00 a. Pulse on a Rope* – 3B10.10 (Demo Room) PULSE ON A ROPE – 3B10.10 - A long rope runs the length of two lecture benches. - One end is attached to a support Rod and the other end to a pulse generator. - Vary the tension to vary the speed of the pulse. b. Wave Model by Wave Machine*# – 3B10.30 (Demo Room) WAVE MODEL BY WAVE MACHINE (Shive Apparatus) – 3B10.30 - Thin rods are mounted on a fine wire that twists easily; - Displace the rod at one end to create a torsion pulse or wave. 2. Longitudinal Pulses and Waves – 3B20.00 a. Hanging Slinky* – 3B20.10 (Jacobs B122 - 163) HANGING SLINKY – 3B20.10 - A long slinky is suspended along a frame. - Stretch and compress the spring quickly to create a pulse or wave. - A spot can be attached to the spring to show that the wave travels and the medium only oscillates. 3. Standing Waves – 3B22.00 a. Vibrating String*# – 3B22.10 (Keck B127 & Jacobs B122 - 279) VIBRATING STRING – 3B22.10 - A string is held under tensions and driven by a variable frequency oscillator. - Changing the frequency will change the number of modes. - Also increasing or decreasing the tension will change the number of modes. b. Standing Waves on the Over Head Projector*# – 3B22.11 STANDING WAVES, OHP – 3B22.11 (Jacobs B122 – 285) - Place the standing wave apparatus on the overhead projector. - Plug in the apparatus and overhead and turn them both on. - Slowly turn the knob on the apparatus until wave patterns appear on the screen or the wall. - The apparatus will show clear patterns of one to seven nodes. c. Resonance in Glass Pipe Filled with Kerosene*# – 3B22.15 RESONANCE IN GLASS PIPE FILLED WITH KEROSENE – 3B22.15 (Demo Room & Jacobs B122-175) - The air inside a very large glass pipe partially filled with kerosene is acoustically excited into standing waves. - Once resonating, the locations of the velocity antinodes inside the pipe are dramatically made evident by vigorous agitation of the fluid, resulting in fabulous foaming frothing fountains of fluid. - The velocity of sound can also be determined by nothing the resonance frequency and measuring the distance between antinodes. 4. Impedance and Dispersion – 3B25.00 a. Impedance with the Wave Machine*# – 3B25.10 (Demo Room) IMPEDENCE WITH THE SHIVE WAVE MACHINE – 3B25.10 - Thin rods are mounted on a fine wire that twists easily. - Displace the rod at one end to create a torsion pulse or wave. - Sets of rods of different lengths are connected to show reflection and refraction with matched or unmatched impedances b. Reflection with the Wave Machine* – 3B25.20 (Demo Room) REFLECTION WITH THE SHIVE WAVE MACHINE – 3B25.20 - Send a single pulse down to the wave machine - Watch the reflected pulse. - Repeat with the end clamped. 5. Compound Waves – 3B27.00 a. Wave Superposition with Wave Machine* – 3B27.15 (Demo Room) WAVE SUPERPOSITION WITH THE SHIVE WAVE MACHINE – 3B27.15 - Attach two Shive models to make a long unit. - Start pulsed from both ends simultaneously. 6. Wave Properties of Sound – 3B30.00 a. Speed of Sound* – 3B30.10 (Jacobs B122 - 275) SPEED OF SOUND – 3B30.10 - A metal surface is hit with a hammer and a flash light is activated instantly. - Two students half a mile away with stop watches; one registers the time when he hears the sound and the other one when he sees the flash light. b. Helium Talk – 3B30.50 (Jacobs B122) HELIUM TALK – 3B30.50 - Talk or laugh while breathing helium. 7. Phase and Group Velocity – 3B33.00 8. Reflection & Refraction (Sound) – 3B35.00 9. Transfer of Energy in Waves – 3B39.00 10. Doppler Effect – 3B40.00 a. Doppler Buzzer*# – 3B40.10 (Demo Room) DOPPLER BUZZER – 3B40.10 - A buzzer and battery are tied to the end of a long string. - Start the buzzer and whirl it in a horizontal circle over your head. - Point out the differences in sounds between the moving and stationary buzzer. 11. Shock Waves – 3B45.00 12. Interference and Diffraction – 3B50.00 a. Ripple Tank – Single Slit* – 3B50.10 (Jacobs B122 - 163) RIPPLE TANK – SINGLE SLIT – 3B50.10 - The shadows from a shallow water tank are reflected on a screen. - Use a plane wave generator with barriers to show single slit diffraction. b. Ripple Tank – Two Points* – 3B50.20 (Jacobs B122 -163) RIPPLE TANK – TWO POINTS – 3B50.20 - The shadows from a shallow water tank are reflected on a screen. - Use two point sources to show interference. c. Ripple Tank – Double Slit* – 3B50.25 (Jacobs B122 -163) RIPPLE TANK – DOUBLE SLIT – 3B50.25 - The shadows from a shallow water tank are reflected onto a screen. - Use the plane wave generator and barriers to make two slits. 13. Interference and Diffraction of Sound – 3B55.00 a. Interference with Two Speakers* – 3B55.10 (Jacobs B122 -165) INTERFERENCE WITH TWO SPEAKERS – 3B55.10 - Two speakers 2m apart are driven from the same oscillator. - The students move their heads around to hear the interference pattern. 14. Beats – 3B60.00 a. Beats with Two Speakers *# – 3B60.10 (Jacobs B122 -165) BEATS WITH TWO SPEAKERS – 3B60.10 - The frequencies of the two function generators are adjusted so that you can hear clear beats from the interaction of the pitches that are coming from the speakers. - An oscilloscope can be used to display the resultant waveform of the beats. 15. Coupled Resonators – 3B70.00 a. Sympathatic Resonance with Tuning Forks* – 3B70.10 SYMPATHETIC RESONANCE WITH TUNING FORKS – 3B70.10 (Jacobs B122 -166) - Use two matched tuning forks on boxes, the open ends facing one another. - Strike one, bring the other close, and then stop the first. ACOUSTICS – 3C00.00 1. The Ear – 3C10.00 2. Pitch – 3C20.00 a. Range of Hearing – 3C20.10 (Jacobs B122 -166) RANGE OF HEARING -3C20.10 - Hook a function generator to a speaker. - Change the pitch as the class listens. - Have the class raise their hands only as long as they can hear at the extreme ends of hearing range. - At subsonic frequencies you can see the speakers vibrate. 3. Intensity and Attenuation – 3C30.00 4. Architectural Acoustics – 3C40.00 5. Wave Analysis and Synthesis – 3C50.00 6. Music Perception and the Voice – 3C55.00 INSTRUMENTS – 3D00.00 1. Resonance in Strings – 3D20.00 2. Stringed Instruments – 3D22.00 3. Resonance Cavities – 3D30.00 a. Resonance Tube*# – 3D30.15 (Jacobs B122) RESONANCE TUBE – 3C30.15 - Use two nested cardboard tubes, open speaker and sine wave generator - Using the plunger tube see the effects of length on the resonant frequencies of closed tubes. - Vary sound source frequency to show open tube resonant frequency pattern. b. Singing Pipe*# – 3D30.40 (Jacobs B122 – 271 & 175) SINGING PIPE – 3C30.40 - An open ended metal or cardboard tube has a metal screen attached inside of one end. - The pipe is heated by putting it up to a to a blow torch with the end that has the metal screen closest. - After 20-30 seconds of heating, the pipe is moved away from the heat source. - If held vertically with the metal screen on the bottom, the pipe will hum as hot air rushes through the tube after being heated while passing through the screen. - Holding the pipe horizontally will stop the sound, but the sound will return if the pipe is returned to vertical while still hot enough. 4. Air Column Instruments – 3D32.00 a. Organ Pipes* – 3D32.10 (Demo Room) ORGAN PIPES – 3D32.10 - There are metal organ pipes of several different lengths with plungers to vary the lengths of the tube or caps for an open or closed pipe. b. Musical Pipes*# – 3D32.25 (Jacobs B122 - 264) MUSICAL PIPES – 3D32.25 - PVC tubes are cut to length as to resonate at a musical frequency. - The pipes are: F: 392 HZ (0.24m); G: 392 HZ (0.213m); A: 440 Hz (0.189m); Bb: 466 Hz (0.178 m); C: 523 Hz (0.158 m); D: 587 Hz (0.140m); E: 659 Hz (0.124m). - Hit the pipes on your palm and compare the notes to the length of the pipes. 5. Resonance in Plates, Bars, Solids – 3D40.00 a. Singing Rod*# – 3D40.20 (Jacobs B122 -286) SINGING ROD -3D40.20 - A long aluminum rod will sing when it is stroked along its length with rosin and supported at its center. - Find the center by balancing the rod on your finger. - Rub some rosin on your free hand and vigorously stroke the rod. - You will need to squeeze hard. Also try holding the rod at a point 1/3 or ź of its length to excite higher harmonics. b. Chladni Plate*# – 3D40.30 (Jacobs B110 –Keck B127) CHLADNI PLATE – 3D40.30 - A square plate is clamped at its center. - Sand is sprinkled on it and place is excited with a mechanical vibrator and a frequency generator. - The sand will show the nodal lines of the excited pattern. - The pattern will change depending on the frequency applied to the mechanical vibrator. c. Shattering the Beaker/ Wine Glass – 3D40.55 (Jacobs B122 -283) SHATTERING THE BEAKER/ WINE GLASS – 3D40.55 - Laboratory beakers or wine glasses are shattered in a chamber when large amplitude sound at the resonant frequency is directed at a beaker or a wine glass. 6. Percussion Instruments – 3D42.00 7. Tuning Forks – 3D46.00 a. Tuning Forks* – 3D46.15 (Jacobs B122 -166) TUNING FORKS – 3D46.15 - Show a set of tuning forks. 8. Electronic Instruments – 3D50.00 SOUND REPRODUCTION – 3E00.00 1. Audio System – 3E10.00 2. Loudspeakers – 3E20.00 3. Microphones – 3E30.00 4. Amplifiers – 3E40.00 5. Recorders – 3E60.00 6. Digital System – 3E80.00 IV. THERMODYNAMICS THERMAL PROPERTIES OF MATTER – 4A00.00 1. Thermometry – 4A10.00 2. Liquid Expansion – 4A20.00 3. Solid Expansion – 4A30.00 a. Bi-Metal Strip* – 4A30.10 (Demo Room) BI-METAL STRIP – 4A30.15 - A bimetal strip is brass on one side and steel on the other. - When heated the strip curves toward the steel side. b. Ball and Ring* – 4A30.20 (Demo Room) BALL AND RING – 4A30.20 - Try putting the ring around a ball. - At room temperature the ring is slightly smaller than the ball. - Heat the ring and try again. 4. Properties of Materials at Low Temperature – 4A40.00 a. Solder Spring*# – 4A40.15 (Jacobs B122) SOLDER SPRING – 4A40.15 - Use solder to make a spring like coil. - Test it with small masses and observe that the coil does not have spring like properties. - Use some extra solder to make another identical coil. - Cool the coil in liquid nitrogen. - After the boiling of liquid nitrogen subsides hang small masses (10Kg) from the coil and observe the spring’s properties the coil has now. b. Smashing a Rose in LN2 – 4A40.30 (Jacobs B122) SMASHING A ROSE IN LN2 – 4A40.30 - Cool a rose in a Dewar of Liquid Nitrogen and smash it. c. Viscous Alcohol* – 4A40.40 (Jacobs B122) VISCOUS ALCOHOL – 4A40.40 - A small beaker of alcohol is cooled in a liquid nitrogen bath. - Before the alcohol freezes, it becomes quite viscous. - Observe the viscous alcohol by pouring it into another beaker. 5. Liquid Helium – 4A50.00 HEAT AND THE FIRST LAW – 4B00.00 1. Heat Capacity and Specific Heat- 4B10.00 2. Convection – 4B20.00 3. Conduction – 4B30.00 4. Radiation – 4B40.00 5. Heat Transfer Applications – 4B50.00 a. Boiling Water in a Paper Cup* – 4B50.20 (Jacobs B122) BOILING WATER IN A PAPER CUP – 4B50.20 - Use a torch to heat an empty paper cup. It catches fire in no time. - Fill another paper cup 1/8 full with water. - Heat the paper cup again and observe that the water boils before the cup catches on fire. 6. Mechanical Equivalent of Heat – 4B60.00 7. Adiabatic Processes – 4B70.00 a. Fire Syringe*#– 4B70.10 (Jacobs B122 - 264) FIRE SYRINGE – 4B70.10 - Insert a small piece of combustible cotton fiber into the syringe piston. - A quick firm stroke on the piston handle produces a flash in the chamber. - The cotton will burn as long as there is air present in the syringe. CHANGE OF STATE – 4C00.00 1. PVT Surfaces – 4C10.00 a. Pressure, Temperature, and Volume Surfaces* - 4C10.10 PRESSURES, TEMPERATURES, AND VOLUME – 4C10.10 (Demo Room) - Surfaces are provided for water and carbon dioxide. - Different surfaces are colored and labeled with the state that the substance in that region. 2. Phase Changes: Liquid – Solid – 4C20.00 a. Hand Warmers (Heat of Crystallization)*# - 4C20.60 HAND WARMERS (HEAT OF CRYSTALIZATION)* – 4C20.60 (Jacobs B122 - 284) - Heat the hand warmers in boiling water until the liquid in vinyl pouches becomes clear. - Push the piezoelectric striker. - Observe a chemical reaction and a change of state from liquid to solid, generating heat in the process. 3. Phase Changes: Liquid – Gas – 4C30.00 4. Cooling by Evaporation – 4C31.00 a. Drinking Bird* – 4C31.30 (Jacobs B122 - 279) DRINGING BIRD – 4C31.30 - Soak the bird’s head in the water and let him “drink”. 5. Dew Point and Humidity – 4C32.00 6. Vapor Pressure – 4C33.00 a. Hand Boiler*# – 4C33.50 (Jacobs B122 - 279) HAND BOILER – 4C33.50 - Hand boiler apparatus filled with colored methyl alcohol fluid. - Cup hand around the bottom chamber. - Note that heat from the hand evaporates the liquid, raising the pressure in the bottom chamber, forcing the liquid into the upper chamber. - Cup hand around the upper chamber. - The same effect applies to send the liquid into the opposite chamber. 7. Sublimation – 4C40.00 8. Phase Changes: Solid – Solid – 4C45.00 9. Critical Point – 4C50.00 a. Critical Opalescence* – 4C50.20 (Jacobs B122 - 279) CRITICAL OPALESCENCE – 4C50.20 - To show the refractive index with phase change. - A mixture of hexane and methanol is heated above 42.4 degrees C. - The mixture is clear and appears as one liquid. - Let the mixture cool to 42.4 degrees C and observe the critical opalescence at the transition temperature by shining a laser beam to the mixture. - As the mixture continues to cool the two liquids will separate into distinct layers. KINETIC THEORY – 4D00.00 1. Brownian Motion – 4D10.00 2. Mean Free Path – 4D20.00 a. Crooke’s Radiometer*# – 4D20.10 (Jacobs B122 - 279) CROOKE’S RADIOMETER – 4D20.10 - Approach a light source near the radiometer and watch the rotation of the vanes. 3. Kinetic Motion – 4D30.00 4. Molecular Dimensions – 4D40.00 5. Diffusion & Osmosis – 4D50.00 GAS LAW – 4E00.00 1. Constant Pressure – 4E10.00 a. Balloon in LN2*# – 4E10.20 (Jacobs B122 - 279) BALOON IN LIQUID NITROGEN – 4E10.20 - An air-filled balloon sits in a dish. - Pour liquid nitrogen over the balloon and watch it shrink. - Take the balloon out and it “blows” back up. 2. Constant Temperature – 4E20.00 3. Constant Volume – 4E30.00 ENTROPY AND THE SECOND LAW – 4F00.00 1. Entropy – 4F10.00 a. Reversible Fluid Mixing*# – 4F10.10 (Jacobs B122 - 264 ) REVERSIBLE FLUID MIXING – 4F10.10 - The space between two cylinders is filled with glycerin. - Colored glycerin is injected into the glycerin between the cylinders. - When the inside cylinder is slowly rotated by means of a crank. - The lines of colored glycerin become mixed with the rest of the glycerin. - In the direction of the rotation is reversed. - The colored glycerin lines reappear by “unmixing” after the same number of rotations in the opposite direction. 2. Heat Cycles – 4F30.00 a. Hero’s Engine with LN2* – 4F30.01 (Jacobs B122 - 285) HERO’S ENGINE WITH LN2 – 4F30.01 - Pour LN2 into the plastic drinking bottle. - Tighten bottle to the cap and PVC pipe assembly. - Hold the other end of the PVC firmly and lower the bottom of the bottle into a Nalgene container 1/3 full of water. - As soon as the bottom of the bottle touches the water, LN2 will begin to boil and pressurize. - The nitrogen gas escaping will cause the bottle to turn at a high rate of speed. b. Stirling Engine*# – 4F30.15 (Jacobs B122 - 273) STERLING ENGINE – 4F30.15 - A sterling engine is placed over a hot or a cold water bath. - The engine rotation will reverse when the direction of the heat flow is reversed. c. Thermoelectric Converter*# – 4F30.80 (Jacobs B122 - 160) THERMOELECTRIC CONVERTER – 4F30.80 - Place one leg of the Thermoelectric Converter into cold water, the other into hot. - The fan turns as the converter draws energy from the hot source (typically a 50 degrees C temperature differential is required) V. ELECTRICITY AND MAGNETISM ELECTROSTATICS – 5A.00 1. Producing Static Charge – 5A10.00 a. Electroscopes*# – 5A10.10 (Demo Room) ELECTROSCOPES – 5A10.10 - Rub friction rods PVC pipes and acrylic using fur, silk, or wool to give it a charge. - Glass rubbed with silk takes on a positive charge as the silk removes electrons from the glass. Amber becomes negatively charged as it strips electrons from fur. - Hold rod close to the electroscope receiver and watch the leaves separate. b. Electric Charge Detector* – 5A10.11 (Jacobs B122 - 374) ELECTRIC CHARGE DETECTOR – 5A10.11 - A simple electroscope that detects an electric charge and determines whether it is positive or negative. - It has a red LED and a transistor. - The gate wire of the transistor acts as an antennae. - Bring any statically charged item toward the apparatus and watch the LED. c. Static Electricity/ Human Powered Light – 5A10.12 (Jacobs B122 - 374) STATIC ELECTRICITY/ HUMAN POWERED LIGHT – 5A10.12 - Hold on to the light bulb wires and walk across a carpeted area dragging the feet as you go. - A charge of static electricity is built up that discharges through the light bulb in the hand. - If enough charge is generated the bulb will glow in free air. d. Electrostatic Charges – “Fun Fly Stick”* – 5A10.13 (Jacobs B122 - 273) ELECTROSTATIC CHARGES – “FUN FLY STICK” – 5A10.13 - The “Fun Fly Stick” is like a mini Van de Graaf Generator. It accumulates charge on its shaft. - This charge can be transferred to a lightweight mylar films. - The mylar films come in an assortment of different shapes - Without any contact with the shaft, the mylar stays suspended in air. 2. Coulomb’s Law – 5A20.00 a. Electroscope a la Van De Graff – 5A20.30 ELECTROSCOPE A LA VAN DE GRAFF – 5A20.30 (Jacobs B122 – Middle Table) - Attach two Mylar balloons to the Van de Graff generator with a fine wire. - Turn on the generator and watch the balloons separate as they take on like charges. 3. Electrostatic Meters – 5A22.00 4. Conductors and Insulators – 5A30.00 5. Induced Charge – 5A40.00 a. Electrostatic Can Roll*# – 5A40.20 (Jacobs B122 - 371) ELECTROSTATIC CAN ROLL – 5A40.20 - Charge a PVC rod with a paper towel and bring it near can and observe the can rolling. 6. Electrostatic Machines – 5A50.00 ELECTRIC FIELDS AND POTENTIAL – 5B00.00 1. Electric Field – 5B10.00 a. Hair on End* – 5B10.10 (Jacobs B122 – Middle Table) HAIR ON END – 5B10.10 - Remove pointed metal items such as keys and microphones. - Stand on the insulated stool. - Turn the power on. - Hold a pointed probe against the sphere. - Place your other hand on the sphere before removing the probe. - Do not remove your hand and stay away from anything metal. - Allow yourself to charge up. Fine, clean, dry hair stands on end the best. - To discharge without shocks, hold pointed probe against the sphere, remove other hand and turn off motor. b. Electric Field Lines* – 5B10.40 (Jacobs B122 - 265) ELECTRIC FIELD LINES – 5B10.40 - Iron filings suspended in oil align with an applied electric field.   - A pan filled with mineral oil is placed on an overhead projector. - Iron filing is sprinkled into the oil. - Different electrodes are inserted in the oil which and are attached to a Van de Graaff generator. - The iron fillings will align in the direction of the electric field. Location: Jacobs B122 - Shelf 265 2. Gauss’ Law- 5B20.00 a. Radio in a Cage*# – 5B20.35 (Jacobs B122 - 374) RADIO IN A CAGE – 5B20.35 - Turn on a transistor radio taped to a pie pan and turn on a 7W fluorescent light source. - You hear static which the radio picks up from the fluorescent light source. - Place the Faraday cage over the radio and cover it with another pie pan and you hear nothing. 3. Electrostatic Potential – 5B30.00 a. Van de Graaf and the Voltmeter* – 5B30.26 VAN DE GRAAF AND THE VOLTMETER – 5B30.15 (Jacobs B122 – 276 & Middle Table) - Use a voltmeter to observe the voltage while varying the charge on the Van de Graaf.. CAPACITANCE – 5C00.00 1. Capacitors – 5C10.00 a. Sample Capacitors* – 5C10.10 (Jacobs B122 - 265) SAMPLE CAPACITORS – 5C10.10 - Show capacitors and capacitor parts and explain. - A capacitor is a device consisting essentially of two conducting surfaces separated by an insulating material or dielectric such as air, paper, mica, glass, plastic film, or oil. It stores electrical energy, blocks the flow of direct current, and permits the flow of alternating current to a degree dependent upon the capacitance and the frequency. 2. Dielectric – 5C20.00 3. Energy Stored in a Capacitor – 5C30.00 a. Light a Bulb with a Capacitor*# – 5C30.30 (Jacobs B122 – 265) LIGHT A BULB WITH A CAPACITOR – 5C30.30 - Connect the power supply to 5600uf capacitor and charge it up. - After the capacitor is fully charged, disconnect the power supply. - Connect the capacitor with a light bulb (<60W). - The bulb lights up for about 10 seconds before the capacitor is completely discharged. RESISTANCE – 5D00.00 1. Resistance Characteristic – 5D10.00 2. Resistivity and Temperature – 5D20.00 a. Wire Coil in Liquid Nitrogen – 5D20.10 WIRE COIL IN LIQUID NITROGEN – 5D20.10 (Jacobs B122 – 158, 213, 228, 300) - Measure the initial resistance of a resistor (a coil of copper wire) at room temperature. - Hook the resistor with a 12V light bulb in series powered by a 30 Volt DC power supply. - The bulb lights dimly or not at all. - Disconnect the circuit and hook it up again with the multi-meter. - Immerse the coil in a cup of liquid nitrogen. - Observe the dramatic drop in the resistance. - Connect the coil with the light bulb and cool it with liquid nitrogen. - Turn the power on and the light bulb glows brightly due to reduced resistance of the coil at a very low temperature. 3. Conduction in Solutions – 5D30.00 4. Conduction in Gases – 5D40.00 ELECTROMOTIVE FORCE AND CURRENT – 5E00.00 1. Electrolysis – 5E20.00 a. Electrolysis of Water* – 5E20.10 (Jacobs B122 - 234) ELECTROLYSIS OF WATER – 5E20.10 - DC passed through slightly acidic water. - Hydrogen and Oxygen gases are formed at the electrodes. - Hydrogen can be collected in a test tube and ignited. 2. Plating – 5E30.00 3. Cells and Batteries – 5E40.00 a. Lemonade Battery*# – 5E40.10 (Jacobs B122 - 265) LEMONADE BATTERY – 5E40.10 - Fill a beaker with lemonade. - Immerse a strip of magnesium and a copper strip in the beaker. - Connect the strips with alligator clips to an LED. - Observe the LED light up. OR - Connect the alligator clips to a battery operated clock (batteries removed). - The clock will start ticking. 4. Thermoelectricity – 5E50.00 5. Piezoelectricity – 5E60.00 DC CIRCUITS – 5F00.00 1. Ohm’s Law – 5F10.00 2. Power and Energy – 5F15.00 3. Circuit Analysis – 5F20.00 4. RC Circuits – 5F30.00 a. Glowing Pickle* – 5F30.30 (Jacobs B122 - 281) GLOWING PICKLE – 5F30.30 - Two nails wired through a variac to 120V household current. - A pickle is placed across the nails. - The pickle will emit a yellow glow. 5. Instruments – 5F40.00 MAGNETIC MATERIALS – 5G00.00 1. Magnets – 5G10.00 a. Break a Magnet* – 5G10.20 (Demo Room) BREAK A MAGNET – 5G10.20 - Show that the magnet attracts iron filings and nails. - Show that an identical broken magnet does the same thing. b. Gauss Rifle* – 5G10.80 (Jacobs B122 - 275) GAUSS RIFLE – 5G10.80 - A series of cube magnets are placed 2.5” apart from each other. - Two steel balls are placed to one side of each magnet - A lone ball is then slowly rolled toward the first magnet, coming in from the opposite side of the sphere pairs. The lone ball will strike the first magnet causing a sphere to be ejected from the opposite side. - This sphere rolls toward the next magnet and s on. - The last ball will fly off with a speed of a few metes per second. Place a soda can in front of it and see it flying. 2. Magnet Domains & Magnetization – 5G20.00 a. Compass Arrays* – 5G20.30 (Demo Room) COMPASS ARRAYS – 5G20.30 - Set out the compass array plates on a table and place a magnet around the edge of plates or in the middle of the plates. - Observe how each of the pieces of steel move when the magnet is moved. 3. Paramagnetism and Diamagnetism – 5G30.00 a. Para/Diamagnetism of Several Samples*# – 5G30.10 PARA/DIAMAGNETISN OF SEVERAL SAMPLES -5G30.10 (Jacobs B122 - 285) - Place pivot base and place the swing arm over the bearing. - Place two samples on the pivot arm- bismuth, water, or cupric sulfate. - Hold magnet very close to the sample but not touching it. - There will be an attraction of cupric sulfate and a repulsion of water or bismuth. b. Paramagnetism of Liquid Oxygen*# – 5G30.20 (Jacobs B122 - 157) PARAMAGNETISM OF LIQUID OXYGEN – 5G30.20 - A metal cone is partially filled with liquid nitrogen and placed over the parallel pole faces of a strong magnet. - Liquid oxygen collects at the point of the cone and drips between the pole faces. - The liquid is attracted to the closest pole face and eventually bridges the gap between the faces. - This demo is small, so a camera is used to display it. 4. Hysteresis – 5G40.00 5. Magnetostriction and Magnetores – 5G45.00 6. Temperature and Magnetism – 5G50.00 a. Curie Point*# – 5G50.15 (Demo Room) CURIE POINT – 5G50.15 - Put a piece of metal near a magnet to show that it is attracted by it. - Heat the metal with a torch until the metal loses its ferromagnetic property and is not attracted by the magnet when put near it. - Once cooled, the metal will again be attracted to the magnet. b. Meissner Effect *( Super Conductivity) – 5G50.50 MEISSNER EFFECT – SUPERCONDUCTIVITY – 5G50.50 (Jacobs B122 – 281 - Place a magnet on warm disk to show how nothing happens, then remove. - Add liquid nitrogen to the Styrofoam container holding the super-conducting disk. - When the boiling stops, the disk is cold. - Use the plastic tweezers to place the magnet on the disk. - The magnet floats over the disk due to magnetic repulsion. MAGNETIC FIELDS AND FORCES – 5H00.00 1. Magnetic Fields – 5H10.00 a. Magnet Pole Detector*# – 5H10.10 (Jacobs B122-264) MAGNET POLE DETECTOR – 5H10.15 - This device will detect the polarity of a bar magnet. - The green LED will light up when the south pole of the magnet is approached to it and the red LED will turn on when the north pole of the magnet is approached to it. - When a non magnetic material is approached to it, the red LED will turn on. b. Dip Needle* – 5H10.15 (Jacobs B115) DIP NEEDLE – 5H10.15 - The dip needle is used to show the local direction of the Earth’s magnetic field. 2. Fields and Currents – 5H15.00 a. Magnetic Field Demonstrator* – 5H15.10 (Jacobs B122 - 276) MAGNETIC FIELD DEMONSTRATOR – 5H15.10 - Place a cylindrical bar magnet in the center of the 4D Magnetic field Demonstrator. - The Iron filing will align with the magnetic field. 3. Forces on Magnets – 5H20.00 a. Levitation Magnets*# – 5H20.20 (Jacobs B122 - 279) LEVITATION MAGNETS – 5H20.20 - Ring magnets sit around a large wood dowel. - The top magnet is pushed down and oscillations are observed. 4. Magnet/Electromagnet Interactions – 5H25.00 5. Force on Moving Charges – 5H30.00 a. Cathode Ray Tube* – 5H30.10 (Jacobs B122 - 274) CHATODE RAY TUBE – 5H30.10 - Plug in the cathode ray tube. - Deflect the beam of the CRT by holding a permanent magnet - If the beam disappears you are holding the magnet too close. 6. Force on Current in Wires – 5H40.00 a. Current Coil, OHP* – 5H40.20 (Jacobs B122 - 280) CURRENT COIL, OHP – 5H40.20 - Connect a piece of slinky to a one terminal of a power supply, about 10-20 volts. - Place the coil on OHP - Tough the other connection from the power supply to the coil momentarily. (Don’t attach it–just touch it). Watch the coil of wire quickly contract as current flows through it. b. Current Balance *# – 5H40.40 (Demo Room) CURRENT BALANCE – 5H40.40 - This demo is used to illustrate the magnetic fields around current carrying wires. - Connect the current balance apparatus to a rheostat and a power supply. - Adjust the balance so that it moves freely that the top wire is above but not resting on the bottom wire. - A laser can be shined to the mirror so that the laser reflection will show clearly on a screen. - Turn on the power supply and apply current gradually. - As more current is applied, the parallel wires will attract or repel each other depending on the direction of the current. c. Homopolar Motor* – 5H40.53 (Jacobs B122 - 276) HOMOPOLAR MOTOR – 5H40.53 -A spherical magnet hangs from a deck screw attracted to the negative terminal of a D cell battery (forming a low-friction bearing). - A wire is used to complete the circuit between the positive terminal of the battery and the magnet. This causes the magnet to spin. OR - Place a battery base on a magnet. - Place the wire loop on top of the battery and see the loop turn. 7. Torques on Coils – 5H50.00 INDUCTANCE – 5J00.00 1. Self Inductance – 5J10.00 2. LR Circuits – 5J20.00 3. RLC Circuits – DC – 5J30.00 ELECTROMAGNETIC INDUCTION – 5K00.00 1. Induced Currents and Forces – 5K10.00 a. Induction Coil with Magnet Galvanometer*# – 5K10.20 INDUCTION COIL WITH MAGNET, GALAANOMETER – 5K10.20 (Jacobs B122 - 274) - A coil of wire is connected to a galvanometer. - A bar magnet is moved in and out of the coil. - The galvanometer deflects; depending on the direction of the motion of the bar magnet or which pole enters first. 2. Eddy Currents – 5K20.00 a. Eddy Current Ring Pivot* – 5K20.01 (Jacobs B122 - 281) EDDY CURRENT RING PIVOT – 5K20.01 - Push the magnet into the ring with the split, nothing happens. - Push the magnet into the other ring, the rings will begin to pivot away from the magnet. - Pull the magnet back towards you and the rings will pivot toward the magnet. b. Eddy Current with a Strong Horseshoe Magnet* – 5K20.10 EDDY CURRENT WITH A STRONG HORSESHOE MAGNET – 5K20.10 (Demo Room) - An aluminum plate is passed through a strong horseshoe magnet. c. Magnets in Eddy Tubes*# – 5K20.25 (Jacobs B122 - 276) MAGNETS IN EDDY TUBES – 5K20.25 - Drop magnets simultaneously down the copper and PVC tube. - The magnet falls through the PVC pipe with no resistance. - The magnet falling through the copper tube takes much longer time to fall. d. Jumping Ring*# – 5K20.30 (Demo Room) JUMPING RING – 5K20.30 - Two aluminum rings are placed around the core of a coin. One ring has a gap. - The apparatus is connected to a variac. - With a ring in place, turn on the switch. The solid ring will jump. - Replace with the ring that has a gap and it will not jump. - Place a coil with bulb attached over the core and note the variation in bulb brightness with position of the coil. - Cool the metal ring with liquid nitrogen and get really a great jump. 3. Transformers – 5K30.00 4. Motors and Generators – 5K40.00 a. DC Motor*# – 5K40.10 (Jacobs B122 - 276) DC MOTOR – 5K40.10 - Place the battery between the uprights. - Place the coil in the bent sections above the magnet. - The coil should start spinning because each half turn the current is flowing through the winding and repelling off the magnet. - As it rotates the current stops but momentum will carry the other side on around until the loop again makes connection with the current from the battery. b. Hand Crank Generator*# – 5K40.80 (Demo Room) HAND CRANK GENERATOR – 5K40.80 - Crank until the lamp shines. AC CIRCUITS – 5L00.00 1. Impedance – 5L10.00 2. LCR Circuits – AC – 5L20.00 a. Puzzle Circuit* – 5L20.25 (Jacobs B122 - 279) PUZZLE CIRCUIT – 5L20.25 - A circuit that looks very much like a series circuit, but the switches and lights do not do what is expected. 3. Filters and Rectifiers – 5L30.00 SEMICONDUCTORS AND TUBES – 5M00.00 1. Semiconductors – 5M10.00 a. Remote Breathing Status Monitor – 5M10.10 (Jacobs B122 - 264) REMOTE BREATHING STATUS MONITOR – 5M10.10 - The apparatus shows the temperature dependence of the electrical conductivity and exponential temperature dependence of the resistance of a sample of semiconductor material - It is used to produce an oscilloscope display that looks like a plot of a person’s inhaled and exhaled air temperature versus time. - A thermistor is placed at the location of the warm exhaled air. - The thermistor resistance will decrease and the current through and the voltage across the resistor in the apparatus will increase. - When the cooler air is inhaled, the thermistor resistance will increase and the current through and the voltage across the resistor will decrease. - The voltage across the resistor of the apparatus is displayed versus time on the oscilloscope screen. - The waveform looks like a plot of inhaled and exhaled air temperature versus time. - The small size and mass of the thermistor make possible rapid change in temperature and resistance. 2. Tubes – 5M20.00 ELECTROMAGNETIC RADIATION – 5N00.00 1. Transmission Lines and Antennas – 5N10.00 2. Tesla Coil – 5N20.00 a. Tesla coil/induction Coil*# – 5N20.10 (Jacobs B122 – 243, 299) TESLA COIL/INDUCTTION COIL – 5N20.10 - Plug in the hand held Tesla coil. - Turn the knob at the base to turn on the coil. It starts to hum. - Hold the coil near a metal object a spark will jump across the tip of the coil to the object. - For added effect hold a fluorescent light bulb to the coil. b. Van De Graaf and Fluorescent Lamp – 5N20.50 VAN DE GRAAF AND FLUORESCENT LAMP – 5N20.50 (Jacobs B122 – 299 and Middle Table) - Bring a fluorescent lamp near the Van De Graaf generator and see it light up. 3. Electromagnetic Spectrum – 5N30.00 a. Projected Spectrum With a Prism – 5N30.10 (Jacobs B122 - 166) PROJECTED SPECTRUM WITH A PRISM – 5N30.10 - White light is projected through a high dispersion prism and onto a screen. b. Microwave Transmitter and Receiver* – 5N30.30 (Jacobs B115) MICROWAVE TRANSMITTER AND RECEIVER – 5N30.30 - Aim the transmitter at the receiver so the horns line up, with the separation between the two about 30 cm. - Turn on the transmitter and the receiver. - Move the receiver closer to the transmitter by a short distance and notice how the signal changes. - Observe the maxima and minima of the wave. VI. OPTICS GEOMETRICAL OPTICS – 6A00.00 1. Speed of Light – 6A01.00 a. Speed of Light* – 6A01.05 (Jacobs B122 - 275) SPEED OF LIGHT- 6A01.05 - Show students a strip which measures the distance traveled by light in one nanosecond. 2. Straight Line Propagation – 6A02.00 3. Reflection from Flat Surfaces – 6A10.00 4. Reflection from Curved Surfaces – 6A20.00 a. Optic Mirage* – 6A20.35 (Jacobs B122 - 280) OPTIC MIRAGE – 6A20.35 -Two Concave mirrors, one with a small hole in it, face each other. - An image of a little pig, placed on the bottom, appears to be floating in the hole. 5. Refractive Index – 6A40.00 a. Disappearing Beaker – 6A40.30 (Jacobs B122 ) DISAPPEARING BEAKER – 6A40.30 - A large beaker is filled half-way with ordinary vegetable oil. - A small beaker is slowly lowered into the oil. - The beaker will “disappear” as it is lowered. - This is due to the fact that Pyrex and vegetable oil have the same index of refraction. b. Disappearing Ball in a Beaker*# – 6A40.31 (Jacobs B122 - 264 ) DISAPPEARING BALL IN A BEAKER – 6A40.31 - A beaker is filled half-way with water. - A gel ball is lowered in the beaker. The gel balls come in very small sizes. They are soaked in water for 24 hours before they are used. - The ball will “disappear” in the water. c. Optical Properties of a Submerged Light Bulb* – 6A40.40 OPTICAL PROPERTIES OF A SUBMERGED LIGHT BULB – 6A40.30 (Jacobs B122 - 275 ) - Submerge a 60 W frosted light bulb in a beaker filled with water. - The frosted part becomes smaller and the glass envelope becomes much larger. - The coating allows the inner glass surface to have total internal reflection. 6. Refraction at Flat Surfaces – 6A42.00 a. Paraffin Prism and Microwaves* – 6A42.55 (Jacobs B122 - 256) PARAFFIN PRISM AND MICROWAVES – 6A42.55 - A large prism made of wax is placed between a microwave transmitter and receiver. - The receiver is moved around the prism until a maximum signal is detected. 7. Total Internal Reflection – 6A44.00 a. Total Internal Reflection Prism* – 6A44.20 (Jacobs B122 - 374) TOTAL INTERNAL REFLECTION PRISM – 6A44.20 - Shine a laser through one side of the prism and observe the final reflected beam leaving the prism perpendicular to the incoming beam. b. Internal Reflection Tubes* – 6A44.40 (Jacobs B122 - 168) INTERNAL REFLECTION TUBES – 6A44.40 - Shine a laser at one end of a long curved plastic tube. - The light travels within most of the tube due to reflection, and illuminates the other end. c. Total Internal Reflection in a Stream of Water*# – 6A44.50 TOTAL INTERNAL REFLECTION IN A STREAM OF WATER – 6A44.50 (Jacobs B122 - 264) - A plastic tube has a hole at the bottom and a cover at the top. - A drainage container is provided to catch the stream of water. - Fill the tube with water. When the cover is removed a jet of water falls in the drainage container - Shine a laser through one side of the prism and observe the water stream. - The laser beam can be seen reflecting off the internal water walls for the length of the stream. 8. Rainbow – 6A46.00 9. Thin Lens – 6A60.00 10. Thick Lens – 6A65.00 a. Choice Oxide* – 6A65.56 (Jacobs B122 - 279) CHOICE EXIDE – 6A65.56 - A sheet of paper has the words CHOICE OXIDE GLASS LAMP printed on it. - When an acrylic rod is placed above the paper, CHOICE OXIDE remains “unchanged”, while GLASS LAMP is inverted and reversed. 11. Pinhole – 6A61.00 12. Optical Instruments – 6A70.00 PHOTOMETRY – 6B00.00 1. Luminosity – 6B10.00 2. Radiation Pressure – 6B30.00 3. Blackbodies – 6B40.00 a. Hole in a Cup* – 6B40.20 (Demo Room) HOLE IN A CUP – 6B40.20 - A white cup has a black lid. - A small hole is cut at the bottom of the cup. - The hole looks more black than the lid even though the inside of the cup is white. DIFFRACTION – 6C00.00 1. Diffraction through One Slit – 6C10.00 a. Single Slit and Laser* – 6C10.10 (Jacobs B122 – 166 & 240) SINGLE SLIT AND LASER – 6C10.10 - A laser shines on a slide containing several single slits. - The diffraction pattern appears on the side wall. - Two different color lasers can be used to demonstrate the wavelength dependence of the pattern. b. Adjustable Slit and Laser*# – 6C10.15 (Jacobs B122 – 166 & 240) ADJUSTABLE SLIT AND LASER – 6C10.15 - A laser shines on an adjustable slit. - The diffraction pattern appears on the side wall. c. Microwave Diffraction* – 6C10.50 (Jacobs B122 - 256) MICROWAVE DIFFRACTION – 6C10.50 - A single slit is placed between a microwave transmitter and receiver. - Move the receiver around to find maxima and minima. 2. Diffraction around Objects – 6C20.00 a. Thin Wire Diffraction*– 6C20.20 (Jacobs B122 - 166) THIN WIRE DIFFRACTION – 6C20.20 - A laser shines on a thin wire. - The pattern is displayed on the side wall. b. Pinhole Diffraction* – 6C20.30 (Jacobs B122 – 166 & 240) PINHOLE DIFFRACTION – 6C20.30 - A laser shines on various sized circular aperture. INTERFERENCE – 6D00.00 1. Interference from two Sources – 6D10.00 a. Double Slit and Laser* – 6D10.10 (Jacobs B122 – 166 & 240) DOUBLE SLIT AND LASER – 6D10.10 - A laser shines on slide containing several pairs of double slits. - The pattern is displayed on the side wall. - Two different color lasers can be used to demonstrate the wavelength dependence of the pattern. b. Microwave Two Source Interference* – 6D10.25 (Jacobs B115) MICROWAVE TWO SOURCE INTERFERENCE – 6D10.25 - Two microwave sources are aimed at a receiver. - The receiver is moved back and forth to find the maxima and the minima. 2. Interference of Polarized Light – 6D15.00 3. Gratings – 6D20.00 a. Multiple Slit* – 6D20.10 (Jacobs B122 – 166 & 240) MULTIPLE SLIT – 6D20.10 - A laser shines on a slide containing various set of slits: 2, 3, 4, and 5 slits. - Two different color lasers can be used to demonstrate the wavelength dependence of the pattern. b. Projected Spectra with Grating* – 6D20.20 (Jacobs B122 – 166 & 300) PROJECTED SPECTRA WITH GRATING – 6D20.20 - The spectrum of a source of light is projected on the side wall using a grating. c. Compact Disc Grating* – 6D20.32 (Jacobs B122 – 240) COMPACT DISC GRATING – 6D20.32 - Shine a laser on a CD to estimate the grooves per inch. d. Crossed Gratings and Laser* – 6D20.50 (Jacobs B122 – 166 & 240) CROSSED GRATINGS AND LASER – 6D20.50 - Two gratings are placed one in front of the other. - A laser shines through the gratings as one is rotated. 4. Thin Films – 6D30.00 a. Newton’s Rings* – 6D30.10 (Jacobs B122 – 279) NEWTON’S RINGS – 6D30.10 - Light is reflected from a thin film of air between a plane of glass and a spherical glass surface. - The image is projected on the side wall. 5. Interferometers – 6D40.00 COLOR – 6F00.00 1. Synthesis and Analysis of Color – 6F10.00 a. Additive and Subtractive Primaries – 6F10.19 ADDITIVE AND SUBTRACTIVE PRIMARIES – 6F10.19 (Jacobs B122 – 166) - A slit and its negative (a slat) is placed on the overhead. - A diffraction grating is placed in front of the overhead lens, resulting in production of two spectra: One “normal” and the other containing colors such as magenta and cyan. b. Hand-Crank Color Mixing Spinner*– 6F10.25 (Jacobs B122 - 286) HAND-CRANK COLOR MIXING SPINNER – 6F10.25 - Chemiluminescent Light Addition is done by snapping the red, blue, and green light sticks and attaching them to the axle. Dim the lights, turn the crank, and observe a circle of white light. - By wrapping black electrical tape on the blue light stick and spinning you can see a band of yellow at the edge of the circle. c. Complementary Spectrum with Slit and Inverted Slit – 6F10.26 (Jacobs B122 – 166 & 293) COMPLEMENTARY SPECTRUM WITH SLIT AND INVERTED SLIT – 6F10.26 - A slit and “inverted slit” used with Hg and a prism produce the normal line spectra and “inverted spectrum” of complementary colors. d. Tri-Color LED* – 6F10.36 (Jacobs B122 - 281) TRI-COLOR LED – 6F10.36 - Push each button in turn to show the 3 colors (RGB) that light up the Plexiglas triangle. - Push each combination of 2 colors to see the resulting color (CMY). - Push all 3 buttons at the same time to show the resulting white light from adding RGB. 2. Dispersion – 6F30.00 3. Scattering – 6F40.00 a. Sunset* - 6F40.10 (Demo Room) SUNSET – 6F40.10 - Pass a beam of white light through a tank of water with scattering centers from a solution of oil in alcohol. - Notice the projected light on the opposite wall change from white to yellow, orange, and finally red. OR - Add a small amount of coffee creamer to water tank - Shine a small flood lamp light into the tank. POLARIZATION – 6H00.00 1. Dichroic Polarization – 6H10.00 a. Microwave Polarization* – 6H10.20 (Jacobs B115) MICROWAVE PLARIZATION – 6H10.20 - Place the microwave speaker and the receiver about half a meter apart or until a reasonable magnitude can be detected. - Place a metal grating between the speaker and the receiver. - Observe how the signal received respond as the grating is rotated. 2. Polarization by Reflection – 6H20.00 a. Brewster’s Angle – 6H20.10 (Demo Room) BREWSTER’S ANGLE – 6H20.10 - Rotate a Polaroid filter in a beam that reflects at Brewster’s angle off a glass (black glass) onto a screen. 3. Circular Polarization – 6H30.00 4. Birefringence – 6H35.00 a. Stress Lines on Plastic – 6H35.50 (Jacobs B122 - 165) STRESS LINES ON PLASTIC – 6H35.50 - Hold a piece of plexiglass between two crossed polarizing filters and squeeze it. - The stress lines of the plastic should become visible. - This demonstration can be done on an overhead projector to make it more visible. 5. Polarization by Scattering – 6H50.00 a. Sunset with Polarizers*– 6H50.10 (Demo Room) SUNSET WITH POLARIZERS – 6H50.10 - Produce a sunset with using the 6F40.10 set up. - When color changes begin, place a Polaroid sheet in front of the tank, parallel to the light beam. - Rotating the sheet will cause the intensity of light to change. THE EYE – 6J00.00 1. The Eye – 6J10.00 2. Physiology – 6J11.00 MODERN OPTICS – 6Q00.00 1. Holography – 6Q10.00 2. Physical Optics – 6Q20.00 VII. MODERN PHYSICS QUANTUM EFFECTS – 7A00.00 1. Photoelectric Effect – 7A10.00 a. h/e Stopping Potential* – 7A10.30 (Jacobs B115) h/e - STOPPING POTENTIAL – 7A10.30 - Filters (450, 500, 550, 600, 650 nm) are placed on a light source shining on a PASCO phototube. - Connected to the apparatus is a voltmeter which displays the stopping potential for a given wavelength of light. - Values of h can be measured within a percent or two. 2. Millikan Oil Drop – 7A15.00 3. Compton Effect – 7A20.00 4. Band Gaps – 7A30.00 a. Cooling LEDs with LN2 – 7A30.10 (Jacobs B122) COOLING LEDs WITH LN2 – 7A30.10 - A green LED and an orange LED are placed in liquid nitrogen and are allowed to cool for 10 seconds (or so). When removed from the nitrogen, both LEDs will have shifted color to yellow. 5. Wave Mechanics – 7A50.00 6. Particle/Wave Duality – 7A55.00 7. X-ray and Electron Diffraction – 7A60.00 8. Condensed Matter – 7A70.00 ATOMIC PHYSICS – 7B00.00 1. Spectra – 7B10.00 a. Student Gratings and Line Source* – 7B10.10 (Jacobs B166) STUDENT GRATINGS AND LINE SOURCE – 7B10.10 - Spectra of various light sources are observed with gratings distributed to the class. b. Project Spectral Lines – Hg – 7B10.20 (Jacobs B122 – 166 & 293) PROJECT SPECTRAL LINES – Hg – 7B10.20 - The spectrum of mercury lamp is projected using diffraction gratings. 2. Absorption – 7B11.00 3. Resonance Radiation – 7B13.00 a. Fluorescence under UV Light* – 7B13.50 (Jacobs B122 – 166 & 299) FLUORESCENCE UNDER UV LIGHT – 7B13.50 - Shine a black light on various minerals causing them to fluorescence. b. Quantum Dots* – 7B13.52 (Jacobs B121) QUANTUM DOTS – 7B13.52 - Quantum dots are small spheres (2-50nm) composed from a semiconductor. - The size of the dots determines the wavelength of light that is emitted. - Various LEDs are used to show that a minimum energy is required to achieve fluorescence. c. Phosphorescence* – 7B13.53 (Jacobs B122 - 274) PHOSPHORESCENCE – 7B13.53 - Shine a blue LED on a piece of “glow-in-the –dark” phosphorescent material. - It absorbs the energy and “stores” it and stores it for a long time as the subatomic reactions required to re-emit the light. 4. Fine Splitting – 7B20.00 5. Ionization Potential – 7B30.00 6. Electron Properties – 7B35.00 7. Atomic Models – 7B50.00 NUCLEAR PHYSICS – 7D00.00 1. Radioactivity – 7D10.00 a. Geiger Counter and Samples* – 7D10.10 (Jacobs B121 or B115) GEIGER COUNTER AND SAMPLES – 7D10.10 -A Geiger counter, with audible beep, is used to measure the activity of various objects, as well as the background. b. Range and Absorption – 7D10.60 (Jacobs B121 or B115 & Jacobs B120) RANGE AND ABSORPTION – 7D10.60 - A radioactive source is placed on one side of a barrier holder and a Geiger counter on the other. Barriers (lead, aluminum, and cardboard) are added until the counts vanish. 2. Nuclear Reactions – 7D20.00 3. Particle Detectors – 7D30.00 a. Diffusion Cloud Chamber – 7D30.60 (Jacobs B122 - 280) DIFFUSION CLOUD CHAMBER – 9D30.60 - Cover base evenly w/ 1” layer of dry ice chunks. - Set chamber on top of dry ice. - Soak all felt pads inside chamber with alcohol & pour a shallow layer of alcohol into chamber. - As apparatus cools down you should see tracks of environmental radioactivity. 4. Nuclear Magnetic Resonance - (NMR) – 7D40.00 5. Models of the Nucleus – 7D50.00 ELEMENTARY PARTICLES – 7E10.00 1. Miscellaneous – 7E10.00 RELATIVITY – 7F00.00 1. Special Relativity – 7F10.00 a. Equivalence Principle – 7F10.10 (Jacobs B122 - 284) EQUIVALENCE PRINCIPLE – 7F10.10 - A long broomstick has a cup attached to the end. - Inside the cup are a ball and a weak spring. - When the ball hangs out of the cup the spring is too weak to pull it back in. - When the stick is raised up in the air and released gravity is instantly switched off. - In the absence of gravity (freefall) the weak spring has the ability to pull the all back into the cup. This apparatus is also called Einstein’s Toy. It was designed by Eric Rogers of Princeton and presented to Einstein on his 76th birthday. b. Geodesics* – 7F10.20 (Jacobs B122 - 278) GEODESICS -7F10.20 - This demo shows how a curve is the shortest distance between two points in a curved space. - Two points on a globe are connected by a straight line and another one curved going through the arctic. - Both distances are measured. - The distance connected through the arctic is shorter. 2. General Relativity – 7F20.00 VIII. ASTRONOMY PLANETARY ASTRONOMY – 8A00.00 1. Solar System Mechanics – 8A10.00 2. Planetary Geology – 8A20.00 STELLAR ASTRONOMY – 8B00.00 1. Miscellaneous – 8B10.00 2. Stellar Evolution – 8B30.00 a. Collapsing Star* (Hoberman Sphere) – 8B30.40 (Jacobs B122 - 283) COLLAPSING STAR (HOBERMAN SPHERE) -8B30.40 - A Hoberman sphere hangs from a pulley and swivel. - The sphere is initially expanded and spun slowly. - The string through the middle of the sphere is then pulled, collapsing the sphere. - The result is a small sphere spinning quite rapidly. b. Gravity Well*# - 8B40.50 (Jacobs B111) GRAVITY WELL -8B40.50 - Roll a ball in the gravity well so that it moves in a circle near the top. - Observe the ball rolling in circles as it slowly drops down into the gravity well. - As the ball drops lower into the well it goes around the circle in a shorter time. - When it approaches the center of the well it zips around so fast that it becomes a blur. - Roll two balls at different positions and observe the relative velocities. COSMOLOGY – 8C00.00 1. Models of the Universe – 8C10.00 2. Black Holes – 8C20.00 IX. ELECTRONICS ELECTRONICS – 9B00.00 1. Lasers – 9B62.00 a. Laser Theory* – Visible Laser – 9B62.10 (Keck SB28) LASER THEORY – VISIBLE LASER – 9B62.10 - A laser has a clear case so the inner workings are visible.     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