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

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

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 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 .

An ideal gas expands according to the law PV^(3//2) =constant We conclude that

In a process, temperature and volume of one mole of an ideal monoatomic gas are varied according to the relation VT= K, where K is a constant. In this process the temperataure of the gas is increased by DeltaT . The amount of heat absorbed by gas is (R is gas constant).

In a process, temperature and volume of one mole of an ideal monoatomic gas are varied according to the relation VT= K, where K is a constant. In this process the temperataure of the gas is increased by DeltaT . The amount of heat absorbed by gas is (R is gas constant).

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 of adiabatic exponent gamma is expanded so that the amount of heat transferred to the gas is equal to the decrease of its internal energy. Then, the equation of the process in terms of the variables T and V is

The pressure of an ideal gas varies according to the law P = P_(0) - AV^(2) , where P_(0) and A are positive constants. Find the highest temperature that can be attained by the gas

An ideal gas whose adiabatic exponent equals gamma expands so that the amount of heat transferred to it is equal to the decrease of its internal energy. Find a. the molar heat capacity of the gas, and b. the T -V equation for the process.