For a gas if `gamma=1.4` , then atomically, `C_p` and `C_v` of the gas are respectively

Two moles on ideal gas with gamma=5/3 is mixed with 3 moles of another ideal non reacting gas with gamma=7/5 .The value of (C_p)/(C_v) for the gasous mixture is closer to :

Ratio of C_(p) and C_(v) of a gas X is 1.4, the number of atom of the gas 'X' present in 11.2 litres of it at NTP will be

For an ideal gas C_(p) and C_(v) are related as

The molar specific heat of an ideal gas at constant pressure and constant volume is C_(p) and C_(v) respectively. If R is the universal gas constant and the ratio of C_(p) to C_(v) is gamma , then C_(v) .

Ratio of C_(p) and C_(v) of a gas 'X' is 1.4 . The number of atoms of the gas 'X' presents in 11.2 "litres" of it a NTP is

Molecules of an ideal gas are known to have three translational degrees of freedom and two rotational degrees of freedom . The gas is maintained at a temperature of T. The total internal energy , U of a mole of this gas, and the value of gamma(= (C_P)/(C_(v))) are given, respectively , by :

T_(c) " and P_(c) of a gas are 400 K and 41 atms respectively . The V_(c) is

Certain amount of an ideal gas is contained in a closed vessel. The vessel is moving with a constant velcity v . The molecular mass of gas is M . The rise in temperature of the gas when the vessel is suddenly stopped is (gamma C_(P) // C_(V))

For hydrogen gas C_p-C_v=a and for oxygen gas C_p-C_v=b , C_p and C_v being molar specific heats. The relation between a and b is