n moles of an ideal gas with constant volume heat capacity `C_(V)` undergo an isobaric expansion by certain volumes. The ratio of the work done in the process, to the heat supplied is:

n moles of an ideal gas with constant volume heat capacity C_V undergo an isobaric expansion by certain volume.The ratio of the work done in the process, to the heat supplied is :

An ideal gas undergoes isobaric expansion at pressure P from volume V_1 to V_2 the work done is :

An amount of heat Q is supplied to a monatomic ideal gas to expand at constant volume .calculatethe ratio of work w done by the gas and the heat supplied .

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

One mole of an ideal gas at 300 K expands from V to 2V volume, then work done W in this process will be …

For one mole of an ideal gas (C_(p) and C_(v) are molar heat capacities at constant presure and constant volume respectively)

The pressure of an ideal gas varies with volume as P= aV, where a is a constant. One mole of the gas is allowed to undergo expansion such that its volume becomes ‘m’ times its initial volume. The work done by the gas in the process is

The molar heat capacity for an ideal monatomic gas is 3R.If dQ is the heat supplied to the gas and dU is the change in its internal energy then for the process the ratio of work done by the gas and heat supplied is equal to

For an ideal monoatomic gas, molar heat capacity at constant volume (C_(v)) is