STATEMENT-1 : `1//4^(th)` of the initial mole of the air is expelled, if air present in an open vessel is heated from `27^(@)C` to `127^(@)C`.
STATEMENT-2 : Rate of diffusion of a gas is inversely proportional to the square root of its molecular mass.

One gm mol of a diatomic gas (gamma=1.4) is compressed adiabatically so that its temper ature rises from 27^(@)C to 127^(@)C . The work done will be

Two mole of an ideal gas is heated at constant pressure of one atmosphere from 27^(@)C to 127^(@)C . If C_(v, m) = 20 + 10^(-2) TJK^(-1) mol^(-1) , then q and Delta U for the process are respectively.

One mole of an ideal gas for which C_(V)= 3//2R heated at a constant pressure of 1 atm from 25^(0)C "to" 100^(0)C What will be the amount of heat change at constant pressure?

One mole of an ideal gas for which C_(V)= 3//2R heated at a constant pressure of 1 atm from 25^(0)C "to" 100^(0)C What will be the amount of work done in the process?

The rate of diffusion of a gas at constant temperature and pressure is a) Directly proportional to its density b) Directly proportional to square root of its molecular wt c) Inversely proportional to its square root of its vapour density d) Directly proportional to its RMS velocity

An open steel vessel has an ideal gas at 27^@C . What fraction of the gas is escaped if the vessel and its contents are heated to 127^@C ? (neglect the expansion of steel)