One mole of an ideal gas at initial temperature T, undergoes a quasi-static process during which the volume V is doubled. During the process, the

Q: One mole of an ideal gas at initial temperature $T$, undergoes a quasi-static process during which the volume $V$ is doubled. During the process, the internal energy $U$ obeys the equation $U=a V^3$, where $a$ is a constant. The work done during this process is

d (d) In the process given, internal energy is $U=a V^3$ $\Rightarrow \quad \frac{f n R T}{2} =a V^3$ where, $f=$ degree of freedom $=3$ (for ideal gas) and $n=$ number of moles $=1$. $\Rightarrow \quad \frac{3}{2} R T=a V^3$ $\Rightarrow \quad \frac{3}{2} p V=a V^3 \quad[\because p V=R T]$ So, pressure in this process is given by $p=\frac{2 a}{3} V^2$ Now, work done during the process is $W=\int \limits_V^{2 V} p d V=\int \limits_V^{2 V} \frac{2 a}{3} V^2 d V$ $=\frac{2 a}{3} \times \frac{1}{3}\left((2 V)^3-V^3\right)$ $=\frac{2 a}{9}\left(7 V^3\right)$ $=\frac{2}{9} \times 7 \times \frac{3}{2} R T \quad\left[\because a V^3=\frac{3}{2} R^2 T\right]$ $=\frac{7}{3} R T$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

One mole of an ideal gas at initial temperature $T$, undergoes a quasi-static process during which the volume $V$ is doubled. During the process, the internal energy $U$ obeys the equation $U=a V^3$, where $a$ is a constant. The work done during this process is

A$\frac{3 R T}{2}$
B$\frac{5 R T}{2}$
C$\frac{5 R T}{3}$
D$\frac{7 R T}{3}$

KVPY 2011, Advanced

STD 11 Science
NEET
STD 11 - 11. thermodynamics
Physics

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