The destiny of a gas A is four times that of gas B. if the molar mass of A is M that of B is

The uncertainties in t he velocities of two particles A and B are 0.05 and 0.02 m s^-1 respectively. The mass of B is five times to that of the mass of A . What is the ratio of uncertainties ((Deltax_A)/(Deltax_B)) in their positions?

1 litre of a gas at STP weights 1.35 gram. The molar mass of the gas is

Two cylinders A and B fitted with pistons contain equal amounts of an ideal diatomic gas at 300K . The piston of A is free to move while that of B is held fixed. The same amount of heat is given to the gas in each cylinder. If the rise in temperature of the gas in B is

The ratio of molar specific heats of certain gas is 1.4, if molar specific heat of gas at constant volume is 4.965 K cal//K mole K , find universal gas constant.

One kg of a diatomic gas is at pressure of 8xx10^4N//m^2 . The density of the gas is 4kg//m^3 . What is the energy of the gas due to its thermal motion?

In a thermodynamic process , pressure of a fixed mass of a gas is changed in such a manner that the gas releases 20J of heat and 8J of work is done on the gas. If the initial internal energy of the gas was 30J . The final internal energy will be

If the volume of the given mass of a gas is increased four times, the temperature is raised from 27^(@)C to 127^(@)C . The elasticity will become

Destiny of a gas is found to be 5.46 g//dm^3 at 27^@C at 2 bar pressure. What will be its destiny at STP?

The density of a gas at 27^@C and 1 bar pressure is 2.56 gL^-1 .Calculate the molar mass.

A welding fuel gas contains carbon and hydrogen only. Burning a small sample of it in oxygen gives 3.38 g carbon dioxide, 0.690g of water and no other products. A volume of 10.0L (measured at STP) of this welding gas is found to weigh 11.7 g. Calculate molar mass of the gas