A quantity of an ideal monoatomic gas consists of n moles initially at temperature `T_(1)` ,The pressure and volume are then slowly doubled in such a manner so as to trace out a straight line on a P-V diagram.For this process,the ratio `(W)/(nRT_(1))` is equal to (where W is work done by the gas):

An ideal mono atomic gas is at temperature T_(0) . The pressure and volume are quasi-statically doubled such that the process traces a straight line on the PV diagram. (a) Calculate the heat absorbed by the gas in the process if number of moles of the gas in the sample is n. (b) Calculate the average molar specific heat capacity of the gas for the process.

One mole of and ideal monoatomic gas is compressed isothermally in a rigid vessel to double its pressure at room temperature, 27^(@)C . The work done on the gas will be :

I mole of an ideal monoatomic gas is expanded till the temperature of the gas is doubled under the process V^(2)T=contant . The initial temperature of the gas is 400K . In terms of R find total work done in the process.

For a monoatomic gas, work done at constant pressure is W. The heat supplied at constant volume for the same rise in temperature of the gas is

One mole of an ideal monoatomic gas at 1 atm, 300 K undergo a process in which pressure of gas is 8 atm then calculate W (in cal).

One mole of an ideal diatomic gas is taken through a process whose P-V diagram is shown in the figure. The work done by the gas is

A quantity of heat Q is supplied to a monoatomic ideal gas which expands at constant pressure. The fraction of heat that goes into work done by the gas ((W)/(Q)) is

Two moles of an ideal monatomic gas, initially at pressure p_1 and volume V_1 , undergo an adiabatic compression until its volume is V_2 . Then the gas is given heat Q at constant volume V_2 . (i) Sketch the complete process on a p-V diagram. (b) Find the total work done by the gas, the total change in its internal energy and the final temperature of the gas. [Give your answer in terms of p_1,V_1,V_2, Q and R ]

One mole of an ideal monoatomic gas at temperature T_0 expands slowly according to the law p/V = constant. If the final temperature is 2T_0 , heat supplied to the gas is