For the reaction,
`SOCI_(2) +H_(2)O rarr SO_(2)+2HCI`
the enthalpy of reaction is `40.0 kJ` and the entropy of reaction is `336 J K^(-1)`. Calculate `DeltaG` at `300K` and predict the neture of the reaction.

In the reaction N_(2(g)) + O_(2(g)) to 2NO_((g)), DeltaH^@ reaction is + 179.9 kJmol^(-1) and DeltaS_("reaction")^@ = 66.09 JK^(-1)mol^(-1) . Calculate DeltaG^@ reaction at 300K.

In the reaction N_(2(g)) + O_(2(g)) to 2NO_((g)), DeltaH^@ reaction is + 179.9 kJmol^(-1) and DeltaS_("reaction")^@ = 66.09 JK^(-1)mol^(-1) . Calculate DeltaG^@ reaction at 300K.

In the reaction N_(2(g)) + O_(2(g)) to 2NO_((g)), DeltaH^@ reaction is + 179.9 kJmol^(-1) and DeltaS_("reaction")^@ = 66.09 JK^(-1)mol^(-1) . Calculate DeltaG^@ reaction at 300K.

In the reaction N_(2(g)) + O_(2(g)) to 2NO_((g)), DeltaH^@ reaction is + 179.9 kJmol^(-1) and DeltaS_("reaction")^@ = 66.09 JK^(-1)mol^(-1) . Calculate DeltaG^@ reaction at 300K.

In a chemical reaction DeltaH is 150 kJ and DeltaS is 100 J K^(-1) at 300 K then DeltaG is :-

underset("Pyridine")overset(SOCI_(2))rarr A+SO_(2) +HCI The product A in the above reaction is

Molar heat capacities at constant pressure for A, B and C are 3, 1.5 and 2 J/K mol. The enthalpy of reaction and entropy of reaction, A +2 B rarr 3C are 20 kJ/mol and 20 J/K mol at 300 K. Calculate DeltaG (in kJ / mol) for the reaction, (1)/(2)A+Brarr(3)/(2)C

Molar heat capacities at constant pressure for A, B and C are 3, 1.5 and 2 J/K mol. The enthalpy of reaction and entropy of reaction, A + B rarr 3C are 20 kJ/mol and 20 J/K mol at 300 K. Calculate DeltaG (in kJ / mol) for the reaction, (1)/(2)A+Brarr(3)/(2)C

Molar heat capacities at constant pressure for A, B and C are 3, 1.5 and 2 J/K mol. The enthalpy of reaction and entropy of reaction, A + B rarr 3C are 20 kJ/mol and 20 J/K mol at 300 K. Calculate DeltaG (in kJ / mol) for the reaction, (1)/(2)A+Brarr(3)/(2)C