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Energy Changes in One Substance. Heating and Cooling Substances Have you ever noticed that it takes practically no time at all for a metal pan to get.

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Presentation on theme: "Energy Changes in One Substance. Heating and Cooling Substances Have you ever noticed that it takes practically no time at all for a metal pan to get."— Presentation transcript:

1 Energy Changes in One Substance

2 Heating and Cooling Substances Have you ever noticed that it takes practically no time at all for a metal pan to get really hot? At the same time, water often takes a fairly long time to change in temperature.

3 Heating and Cooling Substances This is because different materials absorb (or release) heat at different rates The rate of absorbing or releasing heat is called the Specific Heat Capacity

4 Calculating Energy Changes in One Substance Specific heat capacity is defined as the amount of heat required to raise 1 g of a substance 1˚C. Therefore the units for a substance’s specific heat capacity is J/g˚C. The specific heats of several substances will be provided for you in your refrence booklet

5 Heat capacities GENERALLY: Metals have low heat capacities Solids have low heat capacities Liquids have fairly high heat capacities Gases have very large heat capacities

6 Just so you know… McDonald’s produces one of the (thermodynamically speaking) most efficient coffee cups They cup is double walled Basically it is a cup within a cup with a gap in between The gap is filled with cardboard and AIR. Air has a high specific heat = lots of energy needs to be absorbed in order to change in temperature This means it takes a long time for the cup to increase in temperature saving your hand from getting burned.

7 Calculating Energy Changes in One Substance: When the amount of energy in a system changes, it can be measured. Recall that the base unit for energy is the joule (J) If the amount of heat given off by a substance is to be measured, its specific heat capacity must also be known.

8 Calculating Energy Changes: There is a formula we can use to calculate the amount of energy absorbed or released by a system when the temperature changes. It is: Q = mc∆t Q = energy (J) absorbed or released m = mass of the substance (g) c = specific heat capacity (J/g°C) ∆t = change in temperature (°C) t final - t initial

9 Calculating Energy Changes: Please note: When using the Q = mc∆t formula: If heat is absorbed by the system, Q will be positive. If heat is released by the system, Q will be negative. The value of Q itself will always be positive. You need to understand mentally if Q is representing heat being absorbed or heat energy being released; the negative sign is simply representing if it’s absorbed or released

10 Example 1: What quantity of heat is required to raise the temperature of 1.00*10 2 g of liquid water 10.0°C? What was the energy change in the surroundings?

11 Example 2: What quantity of heat is released when 420.0g of lead cools from 85°C to 25°C? The specific heat capacity of lead is 0.13J/g°C.

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