1. Physical Science 13. Heat and Temperature

2. Objectives
Define temperature in terms of the average kinetic energy of atoms or molecules
Convert temperature reading between the Fahrenheit, Celsius, and Kelvin scales
Recognize heat as a form of energy transfer

3. Temperature- a measure of how hot (or cold) something is; specifically, a measure of the average kinetic energy of the particles in an object

4. All particles in a substance are constantly moving
All particles in a substance are constantly moving. Like all moving objects, each particle has kinetic energy.
As the average kinetic energy of an object increases, its temperature will increase.

5. Common thermometers rely on expansion
Thermometer- an instrument that measures and indicates temperature
To measure temperature, we rely on a simple physical property of substances: most objects expand when their temperatures increase.

6. A liquid thermometer uses the expansion of a liquid, alcohol or mercury, to indicate changes in temperature.
The fluid expands as temperature increases and contract as their temperature decreases, because of energy exchange

7. A refrigerator thermometer uses the bending of a strip made from two metals to indicate the correct temperature
A digital thermometer uses changes in electricity to measure temperature

8. Fahrenheit and Celsius are common scales used for measuring temperatures
The units on the Fahrenheit scale are called degrees Fahrenheit, or °F.
On the Fahrenheit scale, water freezes at 32 °F and boils at 212 °F

9. Most countries other than the United States use the Celsius (or centigrade) scale.
The Celsius scale gives a value of 0°C to the freezing point of water and a value of 100°C to the boiling point of water at standard atmospheric pressure
Measured in degrees Celsius, or °C

10. A °C is 1.8 times as large as a °F
Conversion Equations
Write down on index card!!!
Fahrenheit temperature=
(1.8 x Celsius temperature)
TF = 1.8t
Celsius temperature =
(Fahrenheit temperature – 32.0)
1.8
t= (TF-32.0)

11. The Kelvin Scale The Kelvin scale is based on absolute zero
Even in temperatures well below zero the particles of an object are still moving and therefore still have kinetic energy
But how low can the temperature fall?

12. Physically, the lowest possible temperature is -273.16°C
This temperature is absolute zero
At absolute zero the energy of an object is zero
Absolute zero is the basis for the Kelvin scale.

13. On this scale, 0 kelvin, or 0 K, is absolute zero
Absolute zero- the temperature at which molecular energy is at a minimum (0K or °C
There are no negative temperatures on the Kelvin scale

14. Write on index card!!!
Kelvin temperature=
Celsius temperature + 273
T=t + 273

15. Example Temperature
The highest atmospheric temperature ever recorded on Earth was 57.8°C. Express this temperature both in degrees Fahrenheit and in kelvins.
Given: t = 57.8°C
Unknown = TF in °F and T in K
TF = 1.8t +32.0
T=t + 273

16. Assignment In text book turn to page 424
Complete practice problems 1-4
Construct the table seen in #2

17. Relating Temperature to Energy
The feeling associated with temperature difference results from energy transfer
Ex) holding ice
The temperature of ice is lower than the temperature of your hand; therefore, the molecules in the ice move slowly compared with the molecules in your hand. As the molecules on the surface of your hand collide with those on the surface of the ice, energy is transferred to the ice. As a result, the molecules in the ice speed up and their kinetic energy increases. This causes the ice to melt.

18. Temperature changes indicate an energy transfer
Heat- the energy transferred between objects that are at different temperatures
This transfer of energy always takes place from a substance at a higher temperature to a substance at a lower temperature

19. You can use temperature to predict which way energy will be transferred
Internal kinetic energy will be transferred as heat from the warmer object to the cooler object
Ex) you are holding a cup of hot chocolate
When this energy is transferred from the hot water in the cup to your skin, the temperature of the water falls while the temperature of your skin rises

20. When both your skin and the cup in your hand approach the same temperature, less energy is transferred from the cup to your skin.
The greater the difference in the temperatures of the two objects is, the greater the amount of energy that will be transferred as heat is