The temperature of K at which `Delta`G =0 for a given reaction with `Delta`H= -20.5 kJ `mol^(-1)`and` Delta`S =- 50.0 `JK^(-1)mol^(-1)`

At the temperature T(K) for the reaction X_(2)O_(4) (l) rarr 2XO_(2)(g) Delta U = x kJ mol^(-1), Delta S = y JK^(-1) mol^(-1) . Gibbs energy change for the reaction is (Assume X_(2)O_(4), XO_(2) are ideal gases) Delta U = x kJ mol^(-1), Delta S = y JK^(-1) mol^(-1)

The value of log_(10)^(k) for the reaction : A rarr B , If Delta H^(@) = - 55.07 kj "mole"^(-1) at 298K. Delta S^(@) = 10 jK^(-1) "mole"^(-1) at 298 K , R = 8.314 jK^(-1) "mole"^(-1) and 2.303 xx 8.314 xx 298 = 5705 is

Calculate the equilibrium constant (in multiples of 10^(-4) ) for the reaction PCl_(5(g)) rarr PCl_(3(g)) + Cl_(2(g)) at 400K, if Delta H^(0) = 77.2KJ "mole"^(-1) and Delta S^(0) = 122JK^(-1) "mole"^(-1)

What is the melting point of benzene if Delta H_("fusion") = 9.95 kJ//mol and Delta S_("fusion") = 35.7 J//K- mol ?

Assuming that, water vapour is an ideal gas the internal energy (Delta U) when 1 mol of water is vapourised at 1 bar pressure and 100^(@)C (given : molar enthalpy of vaporisation of water at 1 bar and 373 K = 41 kJ mol^(-1) and R = 8.3 J K^(-1) mol^(-1) )) will be

For the reaction at 298 K, 2A+BtoC DeltaH=400 kJ mol^(-1) and DeltaS=0.2 kJ K^(-1)mol^(-1). At what temperature will the reaction becomes spontaneous considering DeltaH and DeltaS to be constant over the temperature range?

For A rarr B, DeltaH= 3.5 kcal mol^(-1), DeltaS= 10 cal mol^(-1) K^(-1) . Reaction is non spontaneous at

For the hypothetical reaction A_(2(g)) + B_(2(g)) hArr 2AB_((g)) Delta_(r ) G^(@) and Delta_(r)S^(@) are 20 kJ/mol and -20 JK^(-1) mol^(-1) respectively at 200K. If Delta_(r)C_(P) is 20 JK^(-1) mol^(-1) then Delta_(r ) H^(@) at 400K is

For the reaction at 300 K A_((g)) harr V_((g)) + S_((g) . Delta_(t) H^(@) = - 30 "KJ/mol" Delta_(t)S^(@) = - 0.1 K.J. K^(-1)."mole"^(-1) What Is the value of equilibrium constant ?