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Question: An ideal gas is taken through a cycle \[A\to B\to C\to A\] as shown in figure. If the net heat suppl...

An ideal gas is taken through a cycle ABCAA\to B\to C\to A as shown in figure. If the net heat supplied in the cycle is 5J5J, then work done by the gas in the process CAC\to A is

Explanation

Solution

According to law of conservation of energy if I eat an apple then the apple will be converted into other forms of energy. The energy my body consumes from the apple can be converted into some work and also by changing my internal energy. This is an example of the first Law of Thermodynamics which is also true for conservation of energy. The energy we intake is equal to the difference of heat transfer to the system and work done by the system.
ΔU=QW\Delta U=Q-W
ΔU=\Delta U=change in Internal energy
Q = heat added by the system
If this heat is released then the system is exothermic and if absorbed then endothermic.

Formula used:
If a system is having the same initial and final position then the internal energy of the system is not changed.
ΔU=zero\Delta U=\text{zero}

Complete answer:
We have been given that the system undergoes a cyclic process and returns to its initial state after a complete cycle. This is an cyclic process
ABCAA\to B\to C\to A
Hence ΔU=0 (1)\Delta U=0\text{ }\left( 1 \right)
According to first law of thermodynamics we have
Q=ΔU+W (2)Q=\Delta U+W\text{ }\left( 2 \right)
Net heat supplied to the system is 5J5J.
Using equation 1 and putting it in 2

& W=5J \\\ & {{W}_{AB}}+{{W}_{BC}}+{{W}_{CA}}=5J \\\ \end{aligned}$$ Here $${{W}_{AB}}=pressure\times change\text{ }in\text{ }volume$$ ![](https://www.vedantu.com/question-sets/d7d2f403-cefd-4146-9204-f8b6904c6f8a1762451980291883872.png) $${{W}_{AB}}=10\times 1=10J$$ As we have no change in volume from $$B\to C$$ Therefore $${{W}_{BC}}=0$$ Hence $${{W}_{CA}}+10J+0=5J$$ $${{W}_{CA}}=-5J$$ **Note:** First law of thermodynamics tells us about the conversion of energy from one form to another but it fails to explain in which direction the energy is flowing for direction purposes we use the 2nd Law of thermodynamics.