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Chapter 15: Q11P (page 412)

Question: (II) Use the conservation of energy to explain why the temperature of a well-insulated gas increases when it is compressed—say, by pushing down on a piston—whereas the temperature decreases when the gas expands. Show your reasoning.

Short Answer

Expert verified

The value of the change in the internal energy is directly related to the value of the temperature. Since in the compression process, the value of the internal energy becomes higher, so the temperature of the system becomes higher. Likewise, in the expansion process, the value of the internal energy is lower, so the temperature of the system becomes lower.

Step by step solution

01

First law of thermodynamics

The first law of thermodynamics says the entire energy of the universe is always conserved. The variation in internal energy of the system is related to the heat transfer to or from the system and the work done on or by the system.

Mathematically, it can be expressed as,

\(\Delta U = Q - W\) … (i)

Here, Q is the heat transfer, W is the work done, and \(\Delta U\) is the change in internal energy.

02

Work done during adiabatic compression process

The gas is well insulated that means there is no heat transfer between system and surroundings. That is\(Q = 0\).

So, the equation (i) can be written as:

\(\Delta U = - W\) … (ii)

During the compression process, the volume of the gas reduces. That indicates the work is done on the system. By convention, work done on the system is negative. By plugging the negative value of work done in the above equation (ii), the change in the internal energy of the system becomes positive. It shows that there is an improvement in the internal energy of the system during compression. An increase in internal energy shows that the temperature of the system increases.

03

Work done during adiabatic expansion process

During the expansion process, the gas is doing work on the surrounding. By convention, work done by the system is positive. By substituting positive work into equation (ii), it indicates that the variation in internal energy becomes negative. That suggests there is a reduction in the system's internal energy, which indicates that the temperature of the system goes down during the expansion of the gas.

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Most popular questions from this chapter

1.0 kg of water at 35°C is mixed with 1.0 kg of water at 45°C in a well-insulated container. Estimate the net change in entropy of the system.

Question: An ideal heat pump is used to maintain the inside temperature of a house at \({T_{{\rm{in}}}} = 22{\rm{^\circ C}}\) when the outside temperature is \({T_{{\rm{out}}}}\). Assume that when it is operating, the heat pump does work at a rate of 1500 W. Also assume that the house loses heat via conduction through its walls and other surfaces at a rate given by \(\left( {650\;{{\rm{W}} \mathord{\left/

{\vphantom {{\rm{W}} {{\rm{^\circ C}}}}} \right.} {{\rm{^\circ C}}}}} \right)\left( {{T_{{\rm{in}}}} - {T_{{\rm{out}}}}} \right)\). (a) For what outside temperature would the heat pump have to operate all the time in order to maintain the house at an inside temperature of 22°C? (b) If the outside temperature is 8°C, what percentage of the time does the heat pump have to operate in order to maintain the house at an inside temperature of 22°C?

Question:(I) The exhaust temperature of a heat engine is 230°C. What is the high temperature if the Carnot efficiency is 34%?

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