The standard Gibbs free energy change `(DeltaG^(@))` at `25^(@)C` for the dissociation of `N_(2)O_(4)(g)` to `NO_(2)(g)` is (given, equilibrium constant = 0.15, R=8.314 `JK^(-) mol^(-1)`)

The standard Gibb's free energy change, DeltaG^(@) is related to equilibrium constant, kp as

What is the value of internal energy change (DeltaU) at 27^(@)C a gaseous reaction 2A_(2)(g)+5B_(2)(g)to2A_(2)B_(5)(g) (whose heat chhange at constant pressure is -50700J)? (R=8.314JK^(-1)" "mol^(-1))

The standard Gibbs energy change for the reaction 2SO_2(g) +O_2(g) to 2SO_3 (g) is -142 kJ mol^(-1) at 300 K. Calculate equilibrium constant.

Using the Gibbs energy change, Delta G^(@)=+ 63.3 kJ , for the following reaction, Ag_(2)CO_(3)hArr2Ag^(+)(aq)+CO_(3)^(2-) the K_(sp) of Ag_(2)CO_(3)(s) in water at 25^(@)C is (R=8.314 JK^(-1)mol^(-1))

Calculate the standard Gibbs free energy change from the free energies of formation data for the following reaction: C_(6)H_(6)(l) +(15)/(2)O_(2)(g) rarr 6CO_(2)(g) +3H_(2)O(g) Given that Delta_(f)G^(Theta) =[C_(6)H_(6)(l)] = 172.8 kJ mol^(-1) Delta_(f)G^(Theta)[CO_(2)(g)] =- 394.4 kJ mol^(-1) Delta_(f)G^(Theta) [H_(2)O(g)] =- 228.6 kJ mol^(-1)