138922 Two ideal gases $A$ and $B$ having the same temperature $T$, same pressure $P$ and same volume $V$, are mixed together. If the temperature of mixture is kept constant and the volume occupied by the mixture is reduced to $\frac{V}{2}$, then the pressure of the mixture will become

138923 The average translational kinetic energy of a molecule in a gas is ' $E_{1}$ '. The kinetic energy of the electron (e) accelerated from rest through Potential difference ' $V$ ', volt is ' $E_{2}$ '. The temperature at which $E_{1}=E_{2}$ is possible, is

138925 How many rotational degrees of freedom does a rigid diatomic molecule have?

138926 The pressure $P$, volume $V$ and temperature $T$ of a gas in the jar $A$ and the other gas in the jar $B$ at pressure $2 P$, volume $V / 4$ and temperature $2 \mathrm{~T}$, then the ratio of the number of molecules in the jar $A$ and $B$ will be

138927 One mole of $\mathrm{O}_{2}$ gas is heated at constant pressure starting at $27^{\circ} \mathrm{C}$. How much energy must be added to the gas as to double its volume?

138922 Two ideal gases $A$ and $B$ having the same temperature $T$, same pressure $P$ and same volume $V$, are mixed together. If the temperature of mixture is kept constant and the volume occupied by the mixture is reduced to $\frac{V}{2}$, then the pressure of the mixture will become

138923 The average translational kinetic energy of a molecule in a gas is ' $E_{1}$ '. The kinetic energy of the electron (e) accelerated from rest through Potential difference ' $V$ ', volt is ' $E_{2}$ '. The temperature at which $E_{1}=E_{2}$ is possible, is

138925 How many rotational degrees of freedom does a rigid diatomic molecule have?

138926 The pressure $P$, volume $V$ and temperature $T$ of a gas in the jar $A$ and the other gas in the jar $B$ at pressure $2 P$, volume $V / 4$ and temperature $2 \mathrm{~T}$, then the ratio of the number of molecules in the jar $A$ and $B$ will be

138927 One mole of $\mathrm{O}_{2}$ gas is heated at constant pressure starting at $27^{\circ} \mathrm{C}$. How much energy must be added to the gas as to double its volume?

138922 Two ideal gases $A$ and $B$ having the same temperature $T$, same pressure $P$ and same volume $V$, are mixed together. If the temperature of mixture is kept constant and the volume occupied by the mixture is reduced to $\frac{V}{2}$, then the pressure of the mixture will become

138923 The average translational kinetic energy of a molecule in a gas is ' $E_{1}$ '. The kinetic energy of the electron (e) accelerated from rest through Potential difference ' $V$ ', volt is ' $E_{2}$ '. The temperature at which $E_{1}=E_{2}$ is possible, is

138925 How many rotational degrees of freedom does a rigid diatomic molecule have?

138926 The pressure $P$, volume $V$ and temperature $T$ of a gas in the jar $A$ and the other gas in the jar $B$ at pressure $2 P$, volume $V / 4$ and temperature $2 \mathrm{~T}$, then the ratio of the number of molecules in the jar $A$ and $B$ will be

138927 One mole of $\mathrm{O}_{2}$ gas is heated at constant pressure starting at $27^{\circ} \mathrm{C}$. How much energy must be added to the gas as to double its volume?

138922 Two ideal gases $A$ and $B$ having the same temperature $T$, same pressure $P$ and same volume $V$, are mixed together. If the temperature of mixture is kept constant and the volume occupied by the mixture is reduced to $\frac{V}{2}$, then the pressure of the mixture will become

138923 The average translational kinetic energy of a molecule in a gas is ' $E_{1}$ '. The kinetic energy of the electron (e) accelerated from rest through Potential difference ' $V$ ', volt is ' $E_{2}$ '. The temperature at which $E_{1}=E_{2}$ is possible, is

138925 How many rotational degrees of freedom does a rigid diatomic molecule have?

138926 The pressure $P$, volume $V$ and temperature $T$ of a gas in the jar $A$ and the other gas in the jar $B$ at pressure $2 P$, volume $V / 4$ and temperature $2 \mathrm{~T}$, then the ratio of the number of molecules in the jar $A$ and $B$ will be

138927 One mole of $\mathrm{O}_{2}$ gas is heated at constant pressure starting at $27^{\circ} \mathrm{C}$. How much energy must be added to the gas as to double its volume?

138922 Two ideal gases $A$ and $B$ having the same temperature $T$, same pressure $P$ and same volume $V$, are mixed together. If the temperature of mixture is kept constant and the volume occupied by the mixture is reduced to $\frac{V}{2}$, then the pressure of the mixture will become

138923 The average translational kinetic energy of a molecule in a gas is ' $E_{1}$ '. The kinetic energy of the electron (e) accelerated from rest through Potential difference ' $V$ ', volt is ' $E_{2}$ '. The temperature at which $E_{1}=E_{2}$ is possible, is

138925 How many rotational degrees of freedom does a rigid diatomic molecule have?

138926 The pressure $P$, volume $V$ and temperature $T$ of a gas in the jar $A$ and the other gas in the jar $B$ at pressure $2 P$, volume $V / 4$ and temperature $2 \mathrm{~T}$, then the ratio of the number of molecules in the jar $A$ and $B$ will be

138927 One mole of $\mathrm{O}_{2}$ gas is heated at constant pressure starting at $27^{\circ} \mathrm{C}$. How much energy must be added to the gas as to double its volume?