For the reaction, `Ag_2O(s)to2Ag(s)+1/2O_2(g),/_\H,/_\S` and T are 40kJ, 100J and 380K respectively Hence `/_\G` in KJ 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.

For the reaction Ag_(2)O(s)rarr 2Ag(s)+1//2O_(2)(g) , which one of the following is true :

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.

The value of DeltaH and DeltaS for the reaction C_"(graphite)"+O_(2(g))to CO_(2(g)) are -100KJ and -100JK^(-1) respectively. The reaction will be spontaneous at :-

The enthalpy change ( DeltaH ) for the reaction Ag_2O(s) hArr 2Ag(s) + 1/2 O_2(g) is 30.54 kJ mol^(-1) and entropy change (DeltaS) is 0.06 kJ K^(-1) mol^(-1) at 1 atm. Calculate the temperature at which DeltaG is equal to zero. Also predict the direction of reaction at a temperature below the calculated temperature.

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 :-

The equilibrium constant for the reaction, Ag_2O(s) hArr2Ag(s) +1/2 O_2 (g) is given by

The temperature at which the given reaction is at equilibrium Ag_(2)O_(s) rightarrow 2Ag(s) + 1/2 O_(2)(g) Delta H = 40.5 kJ mol^(-1) and DeltaS= 0.086 k J mol^(-1) K^(-1)

Consider the reacton C(s) + (1)/(2) O_(2)(g) rarr CO(g) + 200 kJ The signs of Delta S, Delta H and Delta G respectively are

Considering the reaction, C(s) + O_(2)(g) to CO_(2)(g) + 393.5 kJ the signs of DeltaH, DeltaS and DeltaG respectively are: