Container A holds an ideal gas at a pressure `1 xx10^5` Pa and at 300 K. Container B whose volume is 4 times the volume of A has the same ideal gas at 400 K and at a pressure of `5xx10^5`

Before the valve V is opened, the ratio of number of moles of gas in A and B is :

Container A holds an ideal gas at a pressure 1 xx10^5 Pa and at 300 K. Container B whose volume is 4 times the volume of A has the same ideal gas at 400 K and at a pressure of 5xx10^5 Before the valve V is opened, V_A and V_B are rms velocities of the molecules in container A and B then V_A/V_B is:

Container A holds an ideal gas at a pressure 1 xx10^5 Pa and at 300 K. Container B whose volume is 4 times the volume of A has the same ideal gas at 400 K and at a pressure of 5xx10^5 The valve V is adjusted to allow the pressure to equalize, but the temperature of each container is kept constant at the initial value, then the pressure in the two containers is :

The volume of 10 "moles" of an ideal gas at 10 atm and 500 K is

An ideal gas occupies a volume of 2m^(3) at a pressure of 3xx10^(6) p,a the energy of the gas is :

If the volume of an ideal gas decreased by 5% at constant pressure, the increase of pressure is

Vessel A contains an ideal gas at a pressure 5xx10^(5) Pa and is connected with a heat source which maintains its temperature at 300 K . Another vessel B which has four time greater inner volume contains the same gas at a pressure 10^(5) Pa and is connected to a heat source which maintains its temperature at 400 K . What will be the pressure of entire system if two vessels are connected by a narrow tube tap:-

If 4 moles of an ideal gas at 300 K occupy volume of 89 . 6 L , then pressure of the gas will be

5 mole of an ideal gas of volume is expanded against vaccum to make its volume 2 times, then work done by the gas is:

At a constant volume, a quantity of an ideal gas has a pressure of 800 mm Hg at 300 K. At what pressure, the temperature will be halved ?