Calculate the change in molar Gibbs energy of carbon dioxide gas at `20^(@)` C when it is isothermally compressed from 1.0 bar to 2.0 bar.

A quantity of 4.0 moles of an ideal gas at 20^(@)C expands isothermally against a constant pressure of 2.0 atm from 1.0 L to 10.0L. What is the entropy change of the system (in cals)?

Calculate the work done in calories when 5 moles of an ideal gas are compressed isothermally and reversibly from a pressure of 1.5 atm to 15 atm at 27^@C .

Calculate the change in internal energy of 3 .0 mol of helium gas when its temperature is increased by 2. 0 K .

The density of Carbon dioxide at 2.0 atm pressure and 27^0C is :

Calculate the maximum work obtained when 0.75 mol of an ideal gas expands isothermally and reversible at 27^(@)C from 10 L to 20 L Also calculate value of q and Delta U accompanying the process.

Calculate DeltaS for 3 mole of a diatomic ideal gas which is heated and compressed from 298 K and 1 bar to 596 K and 4 bar: [Given: C_(v,m)(gas)=(5)/(2)R,"ln"(2)=0.70,R=2"cal K^(-1)mol^(-1) ]

Calculate entropy change when 10mol of an ideal gas expands reversible and isothermally from an initial volume of 10L to 100L at 300K .

The ratio of the molar heat capacities of an ideal gas is (C_p / C_v = 7/6) . Calculate the change in internal energy of 1.0mole of the gas when its temperature is raised by 50 K , (a) keeping the pressure constant , (b) keeping the volume constant and (c ) adiabatically.

Calculate the entropy change when 2 mol of an idela gas expand isothermally and reversibly from an initial volume of 2 dm^(3) to 20 dm^(3) at 300 K .

An ideal gas expands from 100 cm^(3) to 200 cm^(3) at a constant pressure of 2.0 xx 10^(5) when 50 J of heat is supplied to it. Calculate (a) the change in internal energy of the gas , (b) the number of moles in the gas if the initial temperature is 300K , (C ) the molar heat capacity C_P at constant pressure and (d) the molar heat capacity C_v at constant volume