Standard entropy of `X_(2)` , `Y_(2)` and `XY_(3)` are `60, 40 ` and `50JK^(-1)mol^(-1)` , respectively. For the reaction, `(1)/(2)X_(2)+(3)/(2)Y_(2)rarrXY_(3),DeltaH=-30KJ` , to be at equilibrium, the temperature will be:

Standard entropt of X_(2) , Y_(2) and XY_(3) are 60, 40 and 50JK^(-1)mol^(-1) , respectively. For the reaction, (1)/(2)X_(2)+(3)/(2)Y_(2)rarrXY_(3),DeltaH=-30KJ , to be at equilibrium, the temperature will be:

Standrad entropies of X_(2), Y_(2) and XY_(3) are 60, 40 and "50 JK"^(-1)" mol"^(-1) resepectively. For the reaction (1)/(2)X_(2)+(3)/(2)Y_(2)harr XY_(3), DeltaH=-"30 kJ" to be at equilibrium, the temperature shold be

Standard entropies of X_(2), Y_(2) and XY_(3) are 60, 30 are 50 JK^(-1) mol^(-1) respectively. For the reaction (1)/(2)X_(2)+(3)/(2)Y_(2)hArr XY_(3), Delta H = -30 kJ to be at equilibrium, the temperature should be :

Standard entropy of X _(2) , Y _(2) and X Y _(3) are 60, 40 and 50 J K ^(-1) mol ^(-1) , respectively. For the reaction, 1 / 2 X _(2) + 3 / 2 Y _ (2) to X Y _(3) , DeltaH = -3 0 K J , to be at equilibrium, the temperature will be to be at equilibrium, the temperature will be