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Download The Specific Heat Capacity of Metals
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Transcript
The Specific Heat Capacity of Metals Every substance has a definite specific heat capacity at a given temperature. This is used as a characteristic property together with density, melting point, and freezing point to identify substances. However, it is difficult to determine the specific heat capacity of a solid directly. The heat source and the thermometer canoot be easily immersed in the solid. As a result, the Principle of Heat Exchange is used to determine the specific heat capacity of solids. The Principle of Heat Exchange states that if no heat is lost to the surroundings, the heat gained by the object at the lower temperature is equal to the heat lost by the object at the higher temperature. To determine the specific heat capacity of a solid, the solid is first heated to a known temperature in a liquid bath. They the hot solid is immersed in a cold liquid. A liquid is used which does not react chemically with the solid. Heat is transferred until both components of the mixture reach the same final temperature. In this investigation you use the method of mixtures and the Principle of Heat Exchange to determine the specific heat capacity of a metal. Materials: A metal sample (aluminum, copper, iron, lead, zinc) Hotplate insulated cup 200 ml beaker thermometer 100 ml graduated cylinder electronic balance Procedure: 1. Choose a sample metal. Find the mass of the metal. Record this mass in the table provided. 2. Attach a thread to the metal sample. Suspend the metal in a beaker. Do not let it touch the bottom. Heat the water in a beaker to the boiling point. Allow it to boil for about five minutes so that the metal reaches the temperature of the boiling water. Take the temperature of the water. Assume this is also the temperature of the metal. Record this temperature in the table. 3. Add 100 g of cold water to an insulated cup. Quickly remove the metal sample from the hot water bath. Shake it to remove the excess water. Transfer to the cold water in the cup. 4. Stir thee mixture gently. Record the maximum temperature of the mixture. 5. Use the Principle of Heat Exchange to calculate the specific heat capacity of the metal. Data: Component of Mixture Metal A Water Metal B Water Metal C Water Mass (kg) Temperature (โ) Initial Final Change Specific Heat Capacity (๐ฝ/(๐๐ โ)) 4186 Heat Exchanged (J) 4186 4186 Discussion: 1. Compare the value you obtain with other values obtained for the same metal by the class. 2. Compare the specific heat capacities of the different metals used with their densities. Do this by arranging the metals in order of increasing specific heat capacity in terms of the kinetic molecular model of heat. 3. List possible sources of error whether it raises or lowers the value of specific heat capacity. Suggest modifications to the experiment to overcome the errors.
