2. Chapter 12: Thermal Energy What’s hot and what’s not…

3. Energy Wheel Height Energy Motion Energy Electrical Energy Thermal Energy Wave Energy

4. 12.1 Temperature and Thermal Energy

5. 12.1 Objectives Define temperature and distinguish it from thermal energy. Describe the nature of thermal energy. Define specific heat and calculate heat transfer. Use the Celsius and Kelvin temperature scales and convert between the two scales.

6. Thermodynamics Thermodynamics is the study of heat. Kinetic-Molecular Theory - matter is made up of tiny particles in motion. In hot objects (high energy) the particles move faster, and in cold objects (low energy) they move more slowly. The electromagnetic forces can be thought of as mass-less springs between the molecules.

7. Thermal Energy versus Temperature

8. Thermal Energy is the overall energy of motion of all particles making up the object. Thermal energy depends on the number of particles in the object. Twice the mass gives twice the thermal (kinetic) energy. Temperature is the “hotness” of the object. Temperature does NOT depend on the number of particles in a body. It depends on the average kinetic energy of the particles. Twice the mass gives the same temperature.

9. Temperature Scales Farenheit and RankinCelcius and Kelvin Temperature is a measure of an object’s “hotness”. Absolute zero is the temperature where all molecular motion stops. All thermal energy is removed.

10. Temperature Scales

11. Liquid Nitrogen

12. Thermal Energy Transfer Heat flows from hot to cold. Conduction - the process where heat is transferred when particle collide. The pan handle gets hot as the pan is heated. Convection - the process where heat is transferred by the motion of a fluid. The air from the room heater is blown out on the ground and rises to create circulation. Radiation - the process where heat is transferred by electromagnetic waves. The sun heats the earth from millions of miles away.

13. Walking on Coals

14. Specific Heat The Specific Heat of a material is the amount of energy that must be added to the material to raise the temperature of a unit mass one temperature unit.

15. Specific Heat Measurement Calorimeter - A well insulated device used to measure changes in thermal energy.

16. Air is a Poor Conductor

17. 12.2 Change of State & Laws of Thermodynamics

18. 12.2 Objectives Define heat of fusion and vaporization. State the first and second laws of thermodynamics. Define heat engine, refrigerator, and heat pump. Define entropy.

19. Change of State Four States of Matter: solid, liquid, vapor, and plasma. At the melting point and boiling point all energy goes to the change of state. The temperature stays constant until every molecule has changed state.

20. Heat of Fusion The Heat of Fusion of a material is the amount of energy that must be added to melt it. This seems counter-intuitive. It should be the heat of melting because fusion is making a solid from a liquid. Note Bene: There is NO change in temperature term since temperature is constant during the process.

21. Heat of Vaporization The Heat of Vaporization of a material is the amount of energy that must be added to vaporize it. Note Bene: There is NO change in temperature term since temperature is constant during the process.

22. Summary of Formulas The Heat of Vaporization of a material is the amount of energy that must be added to vaporize it.

23. First Law of Thermodynamics The First Law of Thermodynamics states that the total increase in thermal energy of a system is the sum of the heat added to it and the work done on it. This is a restatement of the Law of Conservation of Energy: Energy is neither created nor destroyed but can change form.

24. Second Law of Thermodynamics The Second Law of Thermodynamics states that natural processes go in a direction that maintains or increases the total entropy of the universe. Things tend to become more and more disordered. Food color drops added to a glass of water demonstrates diffusion and the second law of thermodynamics. Entropy is a measure of the disorder of a system.

25. Second Law of Thermodynamics

26. Engines and Pumps Heat Engine - converts heat energy to work. Heat reservoir produces work and gives heat to cold reservoir. Car Engine – Can you follow the motion of a piston around the cycle when gas explodes?

27. Engines and Pumps Heat Pump - uses work to remove heat energy. Work removes heat from cold reservoir to a heat reservoir.

28. Engines and Pumps Refrigerator – Can you follow the motion of a piston around the cycle when gas explodes? Heat Pump - uses work to remove heat energy. Work removes heat from cold reservoir to a heat reservoir.