For an isobaric process , the ratio of `Delta Q` (amount of heat supplied) to the `Delta W` (work done by the gas) is `(gamma = (C_(P))/(C_(V)))`

In an isobaric process, the ratio of heat supplied to the system (dQ) and work done by the system (dW) for diatomic gas is

In an isobaric process of an ideal gas. The ratio of heat supplied annd work done by the system [i.e.,((Q)/(W))] is

A sample of ideal gas (gamma=1.4) is heated at constant pressure. If an amount of 100 J heat is supplied to the gas, the work done by the gas is a) 28.57 J b) 56.54 J c) 38. 92 J d) 65.38 J

Let Q and W denote the amount of heat given to an ideal gas the work done by it in an isothermal process.

P_(i), V_(i) are initial pressure and volumes and V_(f) is final volume of a gas in a thermodynamic process respectively. If PV^(n) = constant, then the amount of work done by gas is : (gamma = C_(p)//C_(v)) . Assume same, initial states & same final volume in all processes.

Let Q and W denote the amount of heat given to an ideal gas and the work done by it in an adiabatic process.

In a isobaric process the work done by a di-atomic gas is 10 J , the heat given to the gas will be :

During an isobaric heating process the work done by oxygen gas is 4 J. Calculate the amount of heat transferred to the gas. [gamma = 1.4]

A sample of ideal gas (gamma=1.4) is heated at constant pressure. If an amount of 100 J heat is supplied to the gas, the work done by the gas is

An ideal gas undergoes an isobaric process. If its heat capacity is C , at constant volume and number of mole n, then the ratio of work done by gas to heat given to gas when temperature of gas changes by DeltaT is :