For the reaction, `Ag_(2)O(s)hArr2Ag(s)+(1)/(2)O_(2)(g)`
`DeltaH,DeltaS and T` are 40.63 kJ `mol^(-1)`, 108.8 `JK^(-1)mol^(-1) and 373.4K respectively. Free energy change `DeltaG` of the reaction will be:

For a reaction, Ag_(2)O(s)hArr2Ag(s)+(1)/(2)O_(2)(g) DeltaH,DeltaS and T are 40.63 kJ mol^(-1) , 108.8 J K^(-1)mol^(-1) and 373.3K respectively. Predict the feasibility of the reaction:

DeltaH and DeltaS for the reaction: Ag_(2)O(s) rarr 2Ag(s) +(1//2)O_(2)(g) are 30.56 kJ mol^(-1) and 66.0 J JK^(-1) mol^(-1) respectively. Calculate the temperature at which free energy change for the reaction will be zero. Predict whether the forward reaction will be favoured above or below this temperature.

For the reaction, Ag_(2)O(s)rarr2Ag(s)+(1)/(2)O_(2)(g),DeltaH,DeltaS and T are 40kJ, 100J and 380K respectively. Hence DeltaG in kJ is :

For the reaction Ag_(2)O(s)rarr 2Ag(s)+1//2O_(2)(g) the value of Delta H=30.56 KJ mol^(_1) and Delta S = 66 JK^(-1)mol^(-1) . The temperature at which the free energy change for the reaction will be zero is :-

For vaporization of water at 1 atmospheric pressure, the values of DeltaH and DeltaS are 40.63 "kJ mol"^(-1) and 108.8 "JK"^(-1) mol^(-1) respectively. The temperature when Gibbs energy change (DeltaG) for this transformation will be zero , is :

Delta H and Delta S for the reaction, Ag_(2)O(s)to 2A(s)+(1)/(2)O_(2)(g) , are 30.56 kJ mol^(-1) and 66.0 J mol^(-1) respectively. Calculate the temperature at which this reaction will be at equilibrium. Predict whether the forward reaction will be favoured above or below this temperature.