If `C_(p)` and `C_(v)` denote the specific heats of nitrogen per unti mass at constant pressure and constant volume respectively, then

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

If C_(p) and C_(v) denoted the specific heats of unit mass of nitrogen at constant pressure and volume respectively, then

If C_(p) and C_(v) denoted the specific heats of unit mass of nitrogen at constant pressure and volume respectively, then

If for hydrogen C_(P) - C_(V) = m and for nitrogen C_(P) - C_(V) = n , where C_(P) and C_(V) refer to specific heats per unit mass respectively at constant pressure and constant volume, the relation between m and n is (molecular weight of hydrogen = 2 and molecular weight or nitrogen = 14)

If for hydrogen C_(P) - C_(V) = m and for nitrogen C_(P) - C_(V) = n , where C_(P) and C_(V) refer to specific heats per unit mass respectively at constant pressure and constant volume, the relation between m and n is (molecular weight of hydrogen = 2 and molecular weight or nitrogen = 14)

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

When water is heated from 0^(@)C to 4^(@)C and C_(P) and C_(V) are its specific heats at constant pressure and constant volume respectively , then :-