1. Heat

2. What causes the temperatures of two objects placed in thermal contact to change? Something must move from the high temperature object to the low temperature object. Is it matter or energy? If it is matter the mass of the high temperature object would decrease while the mass of the low temperature object would increase. This is not observed. It must be energy flowing between the two objects that causes a change in their temperatures.

3. The energy flowing between the two objects must be on the microscopic level because we can not see it. Energy Review Kinetic energy, KE-the macroscopic energy an object has due to its motion, measured in Joules, J. Gravitational potential energy energy, GPE-the macroscopic energy an object has due to its position, measured in Joules, J. Total mechanical energy, E-the sum of an object’s kinetic and potential energies, measured in Joules, J. Work, W-the process by which the total mechanical energy can be changed, measured in Joules, J.

4. Work and the Related Changes in Macroscopic Energy

5. All macroscopic objects are composed of microscopic objects: atoms and molecules These atoms and molecules are moving so they have a microscopic kinetic energy. These atoms and molecules are subject to conservative forces (gravitational and electrical) so they have a microscopic potential energy. The sum of these microscopic kinetic and potential energies is called Thermal Energy, U.

6. When two objects with different temperatures are placed in thermal contact, thermal energy flows from the higher temperature object to the lower temperature object until thermal equilibrium is reached. The thermal energy that flows between two objects because of a difference in temperature is called heat, Q. Since heat is a form of energy it is measured in Joules, J. For historical reasons another unit of thermal energy or heat is sometimes used: calorie, cal or kilocalorie, kcal. Conversion Factor 1kcal = 4186J Just as work can be positive (done on an object) or negative (done by an object), heat can be positive (flows into an object) or negative (flows out of an object).

7. When work is done on or by an object there is a change in the object’s kinetic energy or its gravitational potential energy or both. The change in kinetic energy is perceived as a change in object’s velocity. The change in gravitational potential energy is perceived as a change in object’s position (height above the reference level). When heat flows into or out of an object there is a change in the object’s thermal energy. How is the change in the thermal energy of an object perceived? A change in thermal energy is perceived as a change in the object’s temperature or phase (solid, liquid, or gas). It has been observed that the change in temperature and the change in phase never occur at the same time.

8. When the temperature is changing the phase remains constant and when the phase is changing the temperature remains constant. or

9. What variables determine the magnitude of the change in temperature? More heat results in a larger change in temperature: change in temperature is directly proportional to the amount of heat.

10. When the same quantity of heat flows into (or out of) a larger mass the change in temperature is less.The change in temperature is inversely proportional to the mass.

11. When the same quantity of heat flows into (or out of) equal masses of different substances the change in temperature is different. The change in temperature depends on the specific heat, c of the substance. The specific heat of a substance is the amount of heat required to change the temperature of 1kg of the substance by 1C°.

12. The substance with the higher specific heat experiences a smaller change in temperature. The change in temperature is inversely proportional to the specific heat.

13. Combing All of the Proportions Heat flow that results in a phase change can not be described by the equation above since during a phase change the temperature remains constant…  T=0. It has been observed that phase changes can only occur at certain temperatures which depend on the particular substance.

14. Temperature remains constant Ice begins melting 0°C 0°C is the melting (or freezing) point of water. As more heat is added the temperature will remain constant as more ice melts. Once all of the ice has melted the addition of more heat will result in an increase in the temperature of the water. Temperature increases

15. Temperature remains constant Water begins boiling 100°C is the boiling point of water. As more heat is added the temperature will remain constant as more water converts to steam. Once all of the water has converted to steam the addition of more heat will result in an increase in the temperature of the steam. Temperature increases

16. What determines how much ice melts or water converts to steam? More heat results in a larger mass of ice melting. The mass of ice melted is directly proportional to the quantity of heat.

17. When the same quantity of heat flows into (or out of) equal masses of the solid phase of different substances, each at its melting point, different masses will melt. The mass that melts depends on the latent heat of fusion, Q f of the substance.

18. The latent heat of fusion of a substance is the quantity of heat required to change 1kg of the solid phase of the substance, at its melting point, to 1kg of liquid at the same temperature. The substance with the greater heat of fusion experiences less melting. The mass melted is inversely proportional to the heat of fusion

19. Combing All of the Proportions There is a similar equation describing the phase change between liquid and gas. Q v is the latent heat of vaporization, the quantity of heat required to change 1kg of the liquid phase of the substance, at its boiling point, to 1kg of gas at the same temperature.

21. Summary of Thermodynamic Properties and Relationships I) Phase Change Temperatures- °C, K, °F A) Melting / Freezing Point, T f B) Boiling Point, T b A) Solid Phase, c solid B) Liquid Phase, c liquid C) Gas (vapor) Phase, c gas 1. c p, constant pressure 2. c v, constant volume

22. A) Latent Heat of Fusion, Q f B) Latent Heat of Vaporization, Q v IV) Thermodynamic Relationships

23. Example: Water T f = 0°C, 273K, 32°F T b = 100°C, 373K, 212°F