The volume of one mole of an ideal gas with adiabatic exponent `gamma=1.4` is vaned according to law `V=a//T` where 'a' is a constant. Find amount of heat absorbed by gas in this process if gas temperature increases by 100 K.

The volume of one mode of an ideal gas with adiabatic exponent gamma is varied according to the law V = a//T , where a is constant . Find the amount of heat obtained by the gas in this process, if the temperature is increased by Delta T .

The volume of one mole of ideal gas with adiabatic exponent is varied according to law V = 1/T . Find amount of heat obtained by gas in this process if gas temperature is increased by 100 K.

An ideal gas with adiabatic exponent gamma is heated at constant pressure. It absorbs Q amount of heat. Fraction of heat absorbed in increasing the temperature is

An ideal gas of adiabatic exponent gamma , expands according to law PV= beta (where beta is the positive constant). For this process the compressibility of the gas is

The ratio of specific heats ( C_(p) and C_(v) ) for an ideal gas is gamma . Volume of one mole sample of the gas is varied according to the law V = (a)/(T^(2)) where T is temperature and a is a constant. Find the heat absorbed by the gas if its temperature changes by Delta T .

The efficiency of an ideal gas with adiabatic exponent 'gamma' for the shown cyclic process would be

An ideal gas with adiabatic exponent gamma is heated isochorically.If it absorbs Q amount heat then, fraction of heat absorbed in increasing the internal energy is

An ideal gas has adiabatic exponenty. It expands according to the law P = alpha V, where is alpha constant. For this process, the Bulk modulus of the gas is