ࡱ>  J:bjbj?? ]]1fD<|z<2WW@ ! ! !<<<<<<<=N@< !  ! !!<_"r4<_"_"_"!"<_" !<_"_"68`s@P5!*A78tJ<0z<W76@_"@,8_"8 ! ! ! :    Physical Science Grade 3 Properties of Objects and Properties of Materials Standards: Differentiate between properties of objects and properties of materials. Compare and contrast states of matter Teacher Background 1. Whats the difference between an object and a material? Material is the stuff that an object is made of. Materials keep their properties even if the shape or size of the piece changes. For example, a piece of glass is a material and a glass bowl is an object. A property of glass would be that it is hard. The hardness of glass does not change no matter how it is used. Properties of an object may include shape, size and weight or mass. These things change with the object whereas the properties of materials are consistent despite the size of the sample. 2. What are the properties of materials and what do they mean? Color what is the overall color of the material. State of matter solid, liquid or gas How it interacts with light or its clarity i.e. opaque, translucent, transparent Hardness or strength easily scratched or it scratches other things Texture rough or smooth How it reacts with heat melting point, boiling point, freezing point Density how tightly packed the stuff is. If it is dense, a small amount will be very heavy, like a rock. If it is lightly packed together, a small amount will be very light, like cotton candy. It pertains to the old joke, which weighs more, a pound of feathers or a pound of steel? Answer: they weigh the same, but they take up very different amounts of space. A pound of steel has a high density, a pound of feathers has a very low density. We will not test of all of these traits, as some are much harder than others to work with in the classroom. Also, density is a difficult concept for elementary age students. Lesson 1 Identifying Objects and Materials Part 1 Materials: Rulers Scales Object Properties Chart Procedure 1. First, students will identify common objects in the room. (ex. Stapler, desk, student, book, pen etc.) 2. Next, have students choose 5 objects in the room, either individually or with a partner. Record the shape, size and weight of the object on the Object Properties Chart. Shape is recorded based on observation. Length can be measured with a ruler. Remind students to use units - inches, feet or centimeters. Weight can be measured with a scale. 3. Students record their measurements and observations in the boxes on Object Properties Chart. 4. Share individual results with a whole class discussion. Part 2 Materials: Hardness scratch items (pennies, nails, quartz) Materials Properties Chart Procedure 1. Identify 5 common materials in the classroom (ex. chalk, wood, rocks, glass, plastic, metal, clay, glue, wax, cotton etc.) 2. Introduce properties of materials: Color what is the overall color of the material. State of matter solid, liquid or gas How it interacts with light or its clarity i.e. opaque, translucent, transparent Hardness or strength easily scratched or it scratches other things Soft scratches a fingernail Soft scratches a Penny Nail scratches a nail Glass scratches a piece of glass Quartz scratches a piece of quartz Texture rough or smooth How it reacts with heat melting point, boiling point, freezing point Density how tightly packed the stuff is. If it is dense, a small amount will be very heavy, like a rock. If it is lightly packed together, a small amount will be very light, like cotton candy. It pertains to the old joke, which weighs more, a pound of feathers or a pound of steel? Answer: they weigh the same, but they take up very different amounts of space. A pound of steel has a high density, a pound of feathers has a very low density. 3. Next, have students choose 5 materials in the room and record them on their Materials Properties Chart. 4. Share individual results with a whole class discussion. Highlight the differences between the properties of objects and the properties of materials. Name _____________________________________________________ Date _____________________________ Object Properties Chart  Object Name Shape Length Weight  1.  2.  3.  4.  5. Name _____________________________________________________ Date _____________________________ Material Properties Chart  Material Name Color Clarity Hardness/Strength State of Matter 1.  2.  3.  4.  5. Lesson 2 - Melting Point: A Property of Materials Background: Chocolate melts right around 94 degrees F. Prep by choosing a small amount of chocolate (or something else). Have enough to give one piece to each group of students. Groups of two or three students work well. Materials: thermometers Re-sealable baggies Temperature Data Sheet Procedure: 1. Review the concept of properties of materials versus properties of objects. Review the vocabulary and some of the properties of materials that were taught previously. Explain that todays lesson will explore the melting point, which is another property of a material. 2. Give each group of students a piece of chocolate. Have the students put their chocolate into a re-sealable baggie. Do not seal the baggie, and place a thermometer in the chocolate. 3. Record the temperature. 4. Next, students will hold the chocolate in their hand. Dont squeeze, just warm it up with your hands. 5. Record the temperature every minute along with the state of the chocolate. Continue to record the temperature for 8- 10 minutes until it is melted. 6. Once all the groups have melted their chocolate, compare the melting point that each group recorded. Discuss how the melting point should be about the same for all groups because chocolate is a material, that will have a consistent melting point. Name __________________________________________Date __________ Temperature Data Sheet Time Temperature Starting time: 0 minutes 1 minute 2 minutes 3 minutes 4 minutes 5 minutes 6 minutes 7 minutes 8 minutes 9 minutes 10 minutes 11 minutes Lesson 3 - Property or Attribute Test for a Material Background: We are going to test the strength of different strings by hanging weights on them until they break. The string needs to be very thin in order for it to break. For weights, you can substitute cups and pennies or washers or rocks or anything and weigh it later. Materials: 3 different strings Pennies (teacher provided) Plastic cups Thread Test Data Sheet Foam (optional) Procedure: 1. Explain that todays lesson is to test the strength of a material. We are going to test different strings in groups and then determine which material is the strongest. 2. Introduce each type of string to the class and allow the class to make predictions about which string they think will be the strongest. 3. In groups of 2 or 3, tie one end of the string to a desk and the other end to a cup. 4. Place foam or something soft under the cup on the floor. (dont let the cup fall a large distance) 5. Add weight to the cup until it breaks. 6. Record the color of the thread and the weight. 7. Repeat the test with all 5 threads. 8. After all strings have been tested, check the results against the predictions and determine which string was the strongest. Name __________________________________________Date __________ Thread Test Data Sheet Before you begin testing the thread, which thread do you predict will be the strongest? _____________________________________ Why? _________________________________________________________________________________________________________________________________________________________________________ Thread Color  Weight      Which thread was the strongest? __________________________________ Was your prediction accurate? _________________________________ Physical Science Grade 3 Compare and Contrast States of Matter Teacher background Everything (matter) in the Universe exists in one of 4 states or phases. These are called the states of matter: Solid Liquid Gas Plasma Each has its own characteristics, all of which are based upon how fast their parts (molecules) are moving. Solid holds its shape, things dont pass through it easily This is because its molecules are only vibrating in place and tightly packed together. They do not have much energy. Liquid takes the shape of its container and flows This is because its molecules vibrate, but also can slide around each other. They have more energy and move more than solid molecules. Gas has no shape and will fill its container. This is because gas molecules are very energetic and move freely in all directions, bouncing into things and each other, filling whatever space it is in. That is why you can smell cookies when you walk into a house, even before you see the cookies. The cookie molecules are bouncing around the room. Plasma Incredibly energized molecules ex. Lightning, stars, the sun etc. Lesson 1 Acting Out the States of Matter Materials: Space in the classroom Procedure: 1. Choose an area of the room where the class can stand. Tell them that they are the smallest parts of water, called molecules. 2. Have them place their hands by their side. They cannot move their feet, only shake in place. (solid) 3. Have them keep their hands at their side, but tell them you are heating them up and giving them more energy. They only have enough energy to move two steps in any direction. (liquid) 4. Again, with hands at their side, you continue to heat them up and now they can walk wherever they would like in the classroom. (Gas ) 5. Now, begin to remove energy. its getting very cold and you are losing energy Now you can only move two steps in any direction. (liquid) 6. Now you are even colder and cannot move your feet at all, only move in place. (solid) 7. Have students return to their seats and answer the following questions: 1. Describe the motion of the smallest parts of a solid? Liquid? Gas? 2. Which state of matter is easiest to pass through? Why? Which is hardest? Why? 3. If you had a solid and a liquid and a gas in a container and you took the top off, which one could escape by itself? 8. Discuss each question with the class. Lesson 2: Changing From Solid to Liquid Background: Students will record the temperature of melting ice in water. The temperature will not warm up past 32 degrees until all the ice is melted. Make sure that the water and ice sit for a bit before you begin taking temperatures to help chill the water. Materials: Beakers ice water thermometers Ice Temperature Data Sheet Procedure: Place one ice cube into a container. Pour in 100 ml of water over the ice into the container. Stir with the thermometer. Record the temperature every minute and write down any observations on your data sheet. Do this for 10 minutes. Graph the results with a bar or line graph. Discuss with the class how the ice cube changed from one state of matter to another. Name __________________________________________Date __________ Ice Temperature Data Sheet Time TemperatureObservations about the Ice Cube 1 minute  2 minutes  3 minutes  4 minutes  5 minutes  6 minutes  7 minutes  8 minutes  9 minutes  10 minutes  Lesson 3 Recreating the Water Cycle Background: Water in a liquid state can be heated into a gas called water vapor. If the water vapor is trapped and cooled, it can be turned back into a liquid. We will attempt to turn the liquid water in the plastic container into water vapor, have it cool on the plastic wrap and return as liquid water into the beaker. Materials: Water plastic wrap beakers plastic container weight (book or other heavy classroom item) Procedure: 1. Demonstrate the full set up to the class before giving out materials. Have students do a dry run set up with out hot water. 2. Pour warm water, almost hot to the touch, about 105 degrees F, into the plastic container. 3. Float the beaker on top of the water in the plastic container. 4. Cover the plastic container with plastic wrap 5. Place a weight on the plastic wrap so that the weight is over the beaker and it cannot move away from the weight. 6. Watch and wait. The warm water will turn into water vapor, cool on the plastic and run into the beaker. 7. As a class discussion or a journal entry, talk about how the water changed from one state to another. 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