Thermal Physics

1. Thermal Physics IDS Physics: Unit 04

2. Temperature • There are many ways to measure temperature • Common stable temperatures were first used as reference points (Fahrenheit) • Fixed temperatures of phase transitions were then used (Centigrade and Celsius) • Absolute scales were later used as we understood the nature of temperature better (Kelvin and Rankin)

3. Temperature

4. Temperature

5. Converting Temperature

6. Example 1 • A child has a fever of 40.3°C. Convert this to the more familiar Fahrenheit scale. • 104.5°F

7. Thermal Energy • All atoms are in motion. • They all have kinetic energy • Translating (moving) • Rotating (spinning) • Oscillating • Kinetic energy associated with molecular motion is called thermal energy

8. Definitions • The chemical potential, thermal, and nuclear energy all combined is called the internal energy of the substance • When thermal energy is transferred from one object to another, we called the transferred energy heat • Temperature is a measure of the thermal energy. It is proportional to the kinetic energy of the moving molecules.

9. A cold Balloon • What will happen to a balloon if you take it outside where it is cold? • How small will it get? • As the kinetic energy of the molecules decreases, so will the temperature. • If the molecules stop moving, there is no KE, so then T must be zero.

10. A new Temperature • We need a new temperature scale that reads ‘zero’ only when all molecules have stopped moving. • This new ‘zero’ is called absolute zero.

13. Absolute Zero • -273 °C is the coldest anything can ever get. • Kelvin is an absolute temperature scale based on the Celsius Scale • The absolute temperature is a measure of the average thermal (kinetic) energy of a substance.

14. Think and Explain • Which has a greater amount of thermal energy? • A: 300 kg snowball • B: 300 g. cup of hot tea? • C: 3000 ton iceburg

15. Thermal Expansion • Demo: heating a copper ball • As the temperature of a substance increases, the average distance between the molecules increase. • This is true for most substances (Water is the notable exception )

16. Linear Expansion

17. Example • Find the change in the width of a 3.0 meter square of ordinary glass as the temperature changes from 40. F down to -10. F • Note: you must convert temperatures to Celsius before computing T

18. Applications • Bridges, Roads and Railways • Filling teeth • Thermostats

21. Thermostats

22. The Blachly Scale • Mr. Blachly invents a new temperature scale: • 100 B is the temperature at which a Twix Bar starts to melt. (30C) • 40 B is the temperature at which a Twix Bar is perfect for eating. (5C) • What is room temperature, 22 C, in B

23. The Blachly Scale

24. Pizza Capacity

25. Heat Capacity • Demo: the candle and the balloon

26. Heat Capacity • All substances will change temperature as they gain thermal energy. • The magnitude of the chance depends on the substance and the mass.

27. Heat Capacity

28. Heat Capacity

29. Example • In order to fill a small tub to wash a toddler, you need to warm up 33.75 kg. of water from 65 F to 105 F. How much energy will you need? (Answer in MJ) • If energy is cheap because you generate it from your wind turbine on your roof, and costs $0.036 for a kW-hr ( 3.6 MJ ), what will it cost to heat the water for the baby’s bath? (Answer in cents).

30. Applications • Feel the leg of your chair and the leg of the table. Are they the same temperature? • Why is the hard floor cold and the carpet warm? • Why do some parts of the pizza burn your mouth and other parts do not?

31. Example #2 • 1.05 MJ of energy is needed to bring a pot of water, starting at room temperature, to its boiling point. What is the mass of the water?