Fixed amount of an ideal monoatomic gas contained in a seeled rigid vessel `(V=24.6 litre)` at `1.0` bas is change in Gibb's energy (in Joule) if entropy of gas `S=10+10^(-2)T(J//K)`

Fixed amount of an ideal mono atomic gas contained in a sealed rigid vessel (V=24.6 litres) at 1.0 bar is heated reversibly form 27^(@)C to 127^(@)C . Determine change in Gibb's energy (in Joule) if entropy of gas S=10 + 10^(-2)T(J//K)

Fixed mass of an ideal gas contained in 10.0L sealed rigid vessel at 1atm is heated from -73^(@)C to 27^(@)C . Calculate change in Gibbs enegry if entropy of gas is a function of temperature as S = 2 +10^(-2)T (J K^(-1)). (1atmL = 0.1kJ)

Fixed mass of an ideal gas collected in a 24.64 litre sealed rigid vessel at 10 atm is heated from -73^(@)C to 27^(@)C calculate change in gibbs free energy if entropy of gas is a function of temperature as S=2+10^(-2)T(J//K)(1atm=0.1kJ)

When "1" mole of an ideal monoatomic gas is compressed adiabatically the internal energy change involved is "24 cals.The temperature rise is

One mole of a monoatomic ideal gas is contained in an insulated and rigid container. It is heated by passing a current of 2A for 10 minutes through a filament of resistance 100Omega . What is change in the internal energy of the gas ?

Two vessels A and B , thermally insulated, contain an ideal monoatomic gas. A small tube fitted with a value connects these vessels. Initially the vessel A has 2 litres of gas at 300K and 2 xx 10^(5)Nm^(-2) pressure while vessel B has 4 litres of gas at 350 K and 4 xx 10^(5)Nm^(-2) pressure. The value is now opened and the system reaches equilibrium in pressure and temperature. Calculate the new pressure and temperature . (R = (25)/(3)J//mol-K)

4g of he gas is expanded isothermally at 300K from litre to 10L. The molar change in entropy is:

Four moles of an ideal gas expand isothermally from 1 litre to 10 litres are 300 K. Calculated the change in free energy of the gas (R 8.314 JK^(-1)mol^(-1)) .