The Relationship Between Heat Capacity at Constant Volume and Constant Pressure

What is the general relationship between the heat capacity at constant volume (Cv) and the heat capacity at constant pressure (Cp)? The general relationship between the heat capacity at constant volume (Cv) and at constant pressure (Cp) for an ideal gas is expressed by the equation Cp = Cv + R, where R is the gas constant.

Heat capacity is a fundamental property of substances that relates changes in heat to changes in temperature. For an ideal gas, the relationship between the heat capacities at constant volume (Cv) and constant pressure (Cp) is an important concept in thermodynamics. The equation Cp = Cv + R represents this relationship, where R is the gas constant.

When a gas undergoes a process at constant volume, the heat capacity is called Cp, and when it undergoes a process at constant pressure, the heat capacity is called Cv. The difference in heat capacities arises from the fact that when a gas expands at constant pressure, work is done by the gas, requiring additional heat input to maintain the temperature.

The gas constant R accounts for this additional heat and is added to the heat capacity at constant volume to obtain the heat capacity at constant pressure. This relationship is derived from the first law of thermodynamics, which considers the internal energy change, heat added, and work done by the system.

In summary, the general relationship Cp = Cv + R illustrates the connection between the heat capacities at constant volume and constant pressure for an ideal gas. Understanding this relationship is crucial in analyzing the thermodynamic behavior of gases and predicting their responses to changes in temperature and pressure.

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