138960 The initial pressure and volume of a gas is ' $P$ ' and ' $V$ ' respectively. First by isothermal process gas is expanded to volume ' $9 \mathrm{~V}$ ' and then by adiabatic process its volume is compressed to ' $V$ ' then its final pressure is (Ratio of specific heat at constant pressure to constant volume $=\frac{\mathbf{3}}{\mathbf{2}}$ )

138961 A diatomic gas $[\gamma=1.4]$ does $200 \mathrm{~J}$ of work when it is expanded isobarically. Find the heat given to the gas in the process.

138962 An ideal gas having pressure $P$, volume $V$ and temperature $T$ is allowed to expand adiabatically until its volume becomes $4 \mathrm{~V}$ while its temperature falls to $T / 2$. The adiabatic exponent of the gas is

138965 A diatomic ideal gas is compressed adiabatically to $\frac{1}{32}$ of its initial volume. If the initial temperature of the gas is $T_{1}$ (in Kelvin) and the final temperature is $\alpha T_{1}$, the value of ' $\alpha$ ' is

138966 An ideal gas is found to obey $\mathrm{pV}^{3 / 2}=$ constant during an adiabatic process. If such a gas initially at a temperature $T$ is adiabatically compressed to half to its initial volume, then its final temperature is

138960 The initial pressure and volume of a gas is ' $P$ ' and ' $V$ ' respectively. First by isothermal process gas is expanded to volume ' $9 \mathrm{~V}$ ' and then by adiabatic process its volume is compressed to ' $V$ ' then its final pressure is (Ratio of specific heat at constant pressure to constant volume $=\frac{\mathbf{3}}{\mathbf{2}}$ )

138961 A diatomic gas $[\gamma=1.4]$ does $200 \mathrm{~J}$ of work when it is expanded isobarically. Find the heat given to the gas in the process.

138962 An ideal gas having pressure $P$, volume $V$ and temperature $T$ is allowed to expand adiabatically until its volume becomes $4 \mathrm{~V}$ while its temperature falls to $T / 2$. The adiabatic exponent of the gas is

138965 A diatomic ideal gas is compressed adiabatically to $\frac{1}{32}$ of its initial volume. If the initial temperature of the gas is $T_{1}$ (in Kelvin) and the final temperature is $\alpha T_{1}$, the value of ' $\alpha$ ' is

138966 An ideal gas is found to obey $\mathrm{pV}^{3 / 2}=$ constant during an adiabatic process. If such a gas initially at a temperature $T$ is adiabatically compressed to half to its initial volume, then its final temperature is

138960 The initial pressure and volume of a gas is ' $P$ ' and ' $V$ ' respectively. First by isothermal process gas is expanded to volume ' $9 \mathrm{~V}$ ' and then by adiabatic process its volume is compressed to ' $V$ ' then its final pressure is (Ratio of specific heat at constant pressure to constant volume $=\frac{\mathbf{3}}{\mathbf{2}}$ )

138961 A diatomic gas $[\gamma=1.4]$ does $200 \mathrm{~J}$ of work when it is expanded isobarically. Find the heat given to the gas in the process.

138962 An ideal gas having pressure $P$, volume $V$ and temperature $T$ is allowed to expand adiabatically until its volume becomes $4 \mathrm{~V}$ while its temperature falls to $T / 2$. The adiabatic exponent of the gas is

138965 A diatomic ideal gas is compressed adiabatically to $\frac{1}{32}$ of its initial volume. If the initial temperature of the gas is $T_{1}$ (in Kelvin) and the final temperature is $\alpha T_{1}$, the value of ' $\alpha$ ' is

138966 An ideal gas is found to obey $\mathrm{pV}^{3 / 2}=$ constant during an adiabatic process. If such a gas initially at a temperature $T$ is adiabatically compressed to half to its initial volume, then its final temperature is

138960 The initial pressure and volume of a gas is ' $P$ ' and ' $V$ ' respectively. First by isothermal process gas is expanded to volume ' $9 \mathrm{~V}$ ' and then by adiabatic process its volume is compressed to ' $V$ ' then its final pressure is (Ratio of specific heat at constant pressure to constant volume $=\frac{\mathbf{3}}{\mathbf{2}}$ )

138961 A diatomic gas $[\gamma=1.4]$ does $200 \mathrm{~J}$ of work when it is expanded isobarically. Find the heat given to the gas in the process.

138962 An ideal gas having pressure $P$, volume $V$ and temperature $T$ is allowed to expand adiabatically until its volume becomes $4 \mathrm{~V}$ while its temperature falls to $T / 2$. The adiabatic exponent of the gas is

138965 A diatomic ideal gas is compressed adiabatically to $\frac{1}{32}$ of its initial volume. If the initial temperature of the gas is $T_{1}$ (in Kelvin) and the final temperature is $\alpha T_{1}$, the value of ' $\alpha$ ' is

138966 An ideal gas is found to obey $\mathrm{pV}^{3 / 2}=$ constant during an adiabatic process. If such a gas initially at a temperature $T$ is adiabatically compressed to half to its initial volume, then its final temperature is

138960 The initial pressure and volume of a gas is ' $P$ ' and ' $V$ ' respectively. First by isothermal process gas is expanded to volume ' $9 \mathrm{~V}$ ' and then by adiabatic process its volume is compressed to ' $V$ ' then its final pressure is (Ratio of specific heat at constant pressure to constant volume $=\frac{\mathbf{3}}{\mathbf{2}}$ )

138961 A diatomic gas $[\gamma=1.4]$ does $200 \mathrm{~J}$ of work when it is expanded isobarically. Find the heat given to the gas in the process.

138962 An ideal gas having pressure $P$, volume $V$ and temperature $T$ is allowed to expand adiabatically until its volume becomes $4 \mathrm{~V}$ while its temperature falls to $T / 2$. The adiabatic exponent of the gas is

138965 A diatomic ideal gas is compressed adiabatically to $\frac{1}{32}$ of its initial volume. If the initial temperature of the gas is $T_{1}$ (in Kelvin) and the final temperature is $\alpha T_{1}$, the value of ' $\alpha$ ' is

138966 An ideal gas is found to obey $\mathrm{pV}^{3 / 2}=$ constant during an adiabatic process. If such a gas initially at a temperature $T$ is adiabatically compressed to half to its initial volume, then its final temperature is