The specific heats of an ideal gas at constant pressure and constant volume are `525J//kg-.^(@)C` and `315J//kg-.^(@)C` respectively. Its density at NTP is

The specific heats of argon at constant pressure and constant volume are 525 J//kg and 315 J//kg , respectively. Its density at NTP will be\

If an ideal gas is heated at constant pressure :

The specific heat capacity of hydrogen at constant'pressure and constant volume are 14280 J kg ^(-1) K ^(-1) and 10110 J kg ^(-1) K ^(-1) respectively. Calculate the value of the universal gas constant.

The molar specific heats of an ideal gas at constant pressure and volume are denotes by C_(P) and C_(upsilon) respectively. If gamma = (C_(P))/(C_(upsilon)) and R is the universal gas constant, then C_(upsilon) is equal to

For an ideal gas, the heat of reaction at constant pressure and constant volume are related as

If C_P and C_V denote the specific heats of nitrogen per unit mass at constant pressure and constant volume respectively, then

The molar specific heats of an ideal gas at constant volume and constant pressure are respectively 4.98 and 6.96 cal mol^(-1) K^(-1) . If the molecular weight of the gas be 32, then calculate the root means square speed of the molecule of the gas at 120^@ C . (1 cal = 4.2 J)

Calculate the rms speed of an ideal monoactomic gas having molecular weight 28 gm/mol at 27^(@)C. if the specific heats at constant pressure and volume are respectively 6.3 J mol^(-1)K^(-1) and 3.14J mol^(-1)K^(-1) respectively

Define molar specific heat capacities of a gas at constant pressure and constant volume. Why are they called 'principal specific heat capacities?

Calculate the value of mechanical equivalent of heat from the following data. Specific heat capacity of air at constant volume and at constant pressure are 4.93 cal//mol-K and 6.90 cal//mol-K respectively. Gas constant R = 8.3 J//mol-K .