One gram sample of oxygen undergoes free expansion from 0.75L to 3.0 L at 298 K. Calculate `DeltaS`, q,w `DeltaH "and" DeltaE`

10g of argon gas is compressed isothermally and reversibly at a temperature of 27^(@)C from 10L to 5L . Calculate q, w, DletaU , and DeltaH for this process. R = 2.0 cal K^(-1) "mol"^(-1), log_(10)2 = 0.30 . Atomic weight of Ar = 40 .

10 g of argon is compressed isothermally and reversibly at a temperature of 27^@C from 10 L to 5L. Calculate , w, DeltaE and DeltaH for the process. R = 2.0 cal K^(-1) mol^(-1), log 2 = 0.30, At. Wt. of argon = 40.

One mole of carbon undergoes incomplete combustion to produce carbon monoxide, Calculate (Delta H - Delta U) for the formation of CO at 298 K. Given R = 8.314 JK^(-1) mol^(-1) .

One mole of carbon undergoes incomplete combustion to produce carbon monoxide, Calculate (Delta H - Delta U) for the formation of CO at 298 K. Given R = 8.314 JK^(-1) mol^(-1) .

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.

2 moles monoatomic ideal gas is expanded isothermally and reversibly from 5 L to 20 L at 27°C. DeltaH , DeltaU , q and w for the process respectively are (log 2 = 0.3)

One mole of a non-ideal gas undergoes a change of state from (2,0 atm, 3.0 L, 100 K) to (4.0 atm, 5.0 L, 250 K) with a change in internal energy, DeltaU=30.0 Latm. The change on enthalpy of process in (L - atm) is

5mol of an ideal gas at 293K is expanded isothermally from an initial pressure 0.4 kPa to a final pressure of 0.1kPa against a constant external pressure of 0.1kPa . a. Calcualte q,w, Delta,U , and DeltaH . b. Calculate the corresponding value of q,w, DeltaU , and DeltaH if the above pressure is carried out reversibly.

A 3 mole sample of a triatomic ideal gas at 300 K is allowed to expand under adiabatic reversible condition from 5L to 40 L . The value of DeltaH is

Consider the following reaction which proceeds in a closed vessel. 3X to 2Y +Z The rate of disappearance of X,-(Delta [X])/(Delta t) is found to be 0.075 mol L^(-) s^(-) calculate (Delta [y])/(Delta t) and ( Delta [Z])/( Delta t)