For vaporization of water at 1 atmospheric pressure the values of `Delta H and Delta S` are `50.63 kJ mol^-1` and `118.8 JK ^(-1) mol^(-1)` respectively. The temperature when Gibbs energy change `(Delta G)` for this transformation will be zero, is

For vaporization of water at 1 atmospheric pressure the values of DeltaH and DeltaS are 40.63KJmol^(-1) and 108JK^(-1)mol^(-1) , respectively. The temperature when Gibbs energy change (DeltaG) for this transformation will be zero is

For vaporization of water at 1 atmospheric pressure the values of DeltaH and DeltaS are 40.63KJmol^(-1) and 108JK^(-1)mol^(-1) , respectively. The temperature when Gibbs energy change (DeltaG) for this transformation will be zero 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 :-

DeltaH and DeltaS for a reaction are +30.558 kJ mol^(-1) and 0.066 kJ mol^(-1) at 1 atm pressure. The temperature at which free energy is equal to zero and the nature of the reaction below this temperature are

The units of DeltaS are JK^(-1) mol^(-1) .

The enthalpy and entropy change for the reaction: Br_(2)(l) + Cl_(2)(g) to 2BrCl(g) are 30 kJ mol^(-1) and 105 JK^(-1) mol^(-1) respectively. The temperature at which the reaction will be in equilibrium is:-

The value for DeltaH_(vap) and Delta S_(vap) for ethanol are respectively 38.594 kJ mol^(-1) and 109.8 JK^(-1) mol^-1 . The boiling point of ethanol will be

A process has Delta H = 8 K J mol^(-1) " and " Delta S = 80JK^(-1) mol^(-1) The temperature at which the process will be in equilibrium is ____________ K.

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.