For the reaction
`N_(2)(g) + 3 H_(2) rightarrow 2NH_(3)(g) `
`Delta H = -85.4 kJ and Delta S = - 188.3 Jk^(-1)`
Calculate the temperature at which Gibs energy change(`Delta G`) is equal to zero. Predict the nature of the reaction at this temperature and above it.

For the reaction N_(2)(g) + 3H_(2) rarr 2NH_(3)(g) Delta H = - 95.4 kJ and Delta S = -198.3 JK^(-1) Calculate the temperature at which Gibbs energy change (Delta G) is equal to zero. Predict the nature of the reaction at this temperature and above it.

For the reaction N_(2)(g) + 3H_(2) rarr 2NH_(3)(g) Delta H = - 95.4 kJ and Delta S = -198.3 JK^(-1) Calculate the temperature at which Gibbs energy change (Delta G) is equal to zero. Predict the nature of the reaction at this temperature and above it.

For the reaction, N_(2)(g) +3H_(2)(g) rarr 2NH_(3)(g) DeltaH =- 95.0 kJ and DeltaS = - 19000 J K^(-1) Calculate the temperature in centigrade at which it will attain equilibrium.

For a hypothetical reaction A(g) + 3B(g) to 2C(g). Delta H = -100 kJ and Delta S = -200 Jk^(-1) . Then the temperature at which the reaction will be in equilibrium is

For the reaction, N_2[g] + 3H_2[g] hArr 2NH_3[g] , Delta H = …

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 :-

H(g) + O(g) rightarrow O - H(g), Delta H for this reaction 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 : C_(2)H_(5)OH(l)+3O_(2)(g)rarr2CO_(2)(g)+3H_(2)O(g) if Delta U^(@)= -1373 kJ mol^(-1) at 298 K . Calculate Delta H^(@)