1 mole of an ideal gas `A(C_(v.m)=3R)` and 2 mole of an ideal gas B are `((C_(v,m)=(3)/(2)R)` taken in a container and expanded reversible and adiabatically from 1 litre of 4 letre starting from initial temperature of 320 K. `DeltaE ` or `DeltaU` for the process is :

1 mole of an ideal gas A ( C_(v,m)=3R ) and 2 mole of an ideal gas B are (C_(v.m)= (3)/(2)R) taken in a constainer and expanded reversible and adiabatically from 1 litre of 4 litre starting from initial temperature of 320K. DeltaE or DeltaU for the process is (in Cal)

1 mole of an ideal gas A ( C_(v,m)=3R ) and 2 mole of an ideal gas B are (C_(v.m)= (3)/(2)R) taken in a constainer and expanded reversible and adiabatically from 1 litre of 4 litre starting from initial temperature of 320K. DeltaE or DeltaU for the process is (in Cal) (Give your answer after divide with 240)

A gas (C_(v.m) = (5)/(2)R) behaving ideally is allowed to expand reversibly and adiabatically from 1 litre to 32 litre. Its initial temperature is 327^(@)C . The molar enthalpy change (in J//mol ) for the process is :

A gas (C_(v.m) = (5)/(2)R) behaving ideally is allowed to expand reversibly and adiabatically from 1 litre to 32 litre. Its initial temperature is 327^(@)C . The molar enthalpy change (in J//mol ) for the process is :

A gas (C_(v.m) = (5)/(2)R) behaving ideally is allowed to expand reversibly and adiabatically from 1 litre to 32 litre. Its initial temperature is 327^(@)C . The molar enthalpy change (in J//mol ) for the process is :

A gas (C_(v.m)=(5)/(2)R) behaving ideally was allowed to expand reversibly and adiabatically from 1 liter to 32 liter . It's initial at temperature was 327^(@) C . The molar enthalpy changes ("in "J//"mole") for the process is

A gas (C_(v.m)=(5)/(2)R) behaving ideally was allowed to expand reversibly and adiabatically from 1 liter to 32 liter . It's initial at temperature was 327^(@) C . The molar enthalpy changes ("in "J//"mole") for the process is