The excluded volume of a gas will be larger, if `(T_(C))/(P_(C))` is :

Is the excluded volume of a real gas equal to the actual E volume of the molecules of a gas ?

The ratio of excluded volume ( b ) to molar volume of a gas molecule is

Two moles of a gas at temperature T and volume V are heated to twice its volume at constant pressure. If (C _(p))/(C _(v)) = gamma then increase in internal energy of the gas is-

An ideal gas with pressure P, volume V and temperature T is expanded isothermally to a volume 2V and a final pressure P_i, If the same gas is expanded adiabatically to a volume 2V, the final pressure P_a. The ratio of the specific heats of the gas is 1.67. The ratio (P_a)/(P_1) is .......

An ideal gas with pressure P, volume V and temperature T is expanded isothermally to a volume 2V and a final pressure P_i, If the same gas is expanded adiabatically to a volume 2V, the final pressure P_a. The ratio of the specific heats of the gas is 1.67. The ratio (P_a)/(P_1) is .......

Two moles of an ideal gas with (C_(P))/(C_(V))= (5)/(3) are mixed with 3 moles of another ideal gas with (C_(P))/(C_(V))= (4)/(3) . The value of (C_(P))/(C_(V)) for the mixture is

For a certain gas P_(c) and T_(c) are 80atm and -33^(@)C respectively then V_(C) of the gas will be approximately [Take R=(1)/(2)" Ltr atm mol"^(-1)K^(-1) ]

Two containers of equal volume contain the same gas at pressure P_(1) and P_(2) and absolute temperature T_(1) and T_(2) , respectively. On joining the vessels, the gas reaches a common pressure P and common temperature T . The ratio P//T is equal to

Two containers of equal volume contain the same gas at pressure P_(1) and P_(2) and absolute temperature T_(1) and T_(2) , respectively. On joining the vessels, the gas reaches a common pressure P and common temperature T . The ratio P//T is equal to

P_(i), V_(i) are initial pressure and volumes and V_(f) is final volume of a gas in a thermodynamic process respectively. If PV^(n) = constant, then the amount of work done by gas is : (gamma = C_(p)//C_(v)) . Assume same, initial states & same final volume in all processes.