An ideal gas undergoes a polytropic given by equation P V^n= constant. If molar heat capacity of gas during this process is arithmetic mean of

Q: An ideal gas undergoes a polytropic given by equation $P V^n=$ constant. If molar heat capacity of gas during this process is arithmetic mean of its molar heat capacity at constant pressure and constant volume then value of $n$ is ..............

b (b) Polytropic process $P V^m=$ constant Given heat capacities is average of $C_P$ and $C_V$ So $C=\frac{C_P+C_V}{2}$ or $\quad C=\frac{2 C_V+R}{2}$ or $\quad C=\frac{C_V+R}{2} \quad \dots (i)$ Now formula for specific heat of polytropic process is given by $C=\frac{R}{y-1}+\frac{R}{1-n} \quad \dots (ii)$ or $\frac{R}{y-1}+\frac{R}{2}=\frac{R}{y-1}+\frac{R}{1-n}$ as $C_V=\frac{R}{y-1}$ $\frac{R}{2}=\frac{R}{1-n}$ or $n=-1$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

An ideal gas undergoes a polytropic given by equation $P V^n=$ constant. If molar heat capacity of gas during this process is arithmetic mean of its molar heat capacity at constant pressure and constant volume then value of $n$ is ..............

A$0$
B$-1$
C$+1$
D$\gamma$

Diffcult

STD 11 Science
NEET
STD 11 - 11. thermodynamics
Physics

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