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

The specific heats C_rho and C_v of a perfect gas are reflected at

Why is C_p > C_v ?

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) .

What is the value of gamma=C_p/C_v , if the gas has f degrees of freedom?

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

For a gas R/C_V = 0.4, where R is the universal gas constant and C, is molar specific heat at constant volume. The gas is made up of molecules which are

An insulator container contains 4 moles of an ideal diatomic gas at temperature T. Heat Q is supplied to this gas , due to which 2 moles of the gas are dissociated into atoms but temperature of the gas remains constant . Then

C_(p) nad C_(v) are specific heats at constant pressure and constant volume respectively. It is observed that C_(p)-C_(v)=a for hydrogen gas C_(p)-C_(v)=b for niotrogen gas The correct relation between a and b is

A diatomic gas ( gamma = 1.4) does 300 J work when it is expanded isobarically. The heat given to the gas in this process is

The work of 146 kJ is performed in order to compress one kilo mole of a gas adiabatically and in this process the temperature of the gas increases by 7^@C . The gas is (R=8.3ml^-1Jmol^-1K^-1)