`DeltaG^(c-)` or the reaction is `,`
`4Al+3O_(2)+6H_(2)O+4overset(c-)(O)H rarr 4 Al(OH)_(4)^(c-)`
`E^(c-)._(cell)=2.73V`
`Delta_(f)G^(c-)._((overset(c)(O)H))=-157k J mol^(-1)`
`Delta_(f)G^(c-)._((overset(c-)(H2O))=-237k J mol^(-1)`

(a)`-3.16xx10^(3)kJ mol^(-1)`
(b)`-0.79xx10^(3)kJmol^(-1)`
(c)`-0.263xx10^(3)k J mol^(-1)`
(d)`+0.263xx10^(3)k J mol^(-1)`

Calculate Delta_(r)G^(c-) of the reaction : Ag^(o+)(aq)+Cl^(c-)(aq) rarr AgCl(s) Given :Delta_(f)G^(c-)._(AgCl)=-109kJ mol ^(-1) Delta_(f)G^(c-)_((Cl^(c-)))=-129k J mol ^(-1) Delta_(f)G^(c-)._((Ag^(o+)))=-77 kJ mol ^(-1)

Consider the reaction: 4NH_(3)(g) +5O_(2)(g) rarr 4NO(g) +6H_(2)O(l) DeltaG^(Theta) =- 1010.5 kJ Calculate Delta_(f)G^(Theta) [NO(g)] if Delta_(f)G^(Theta) (NH_(3)) = -16.6 kJ mol^(-1) and Delta_(f)G^(Theta) [H_(2)O(l)] =- 237.2 kJ mol^(-1) .

Calculated the equilibrium constant for the following reaction at 298K : 2H_(2)O(l) rarr 2H_(2)(g) +O_(2)(g) Delta_(f)G^(Theta) (H_(2)O) =- 237.2 kJ mol^(-1),R = 8.314 J mol^(-1) K^(-1)

The rusting of iron takes place as follows : 2H^(o+)+2e^(-) +(1)/(2)O_(2)rarr H_(2)O(l)," "E^(c-)=+1.23V Fe^(2+)+2e^(-) rarr Fe(s)," "E^(c-)=-0.44V Calculae DeltaG^(c-) for the net process. (a) -322kJ mol^(1) (b) -161kJ mol^(-1) (c) -152kJ mol^(-1) (d) -76kJ mol^(-1)

For the reaction: CO(g) +H_(2)O(g) hArr CO_(2)(g) +H_(2)(g) (Delta_(r)H)_(300K) = - 41.2 kJ mol^(-1) (Delta_(r)H)_(1200K) =- 33.0 kJ mol^(-1) (Delta_(r)S)_(300K) = - 4.2 xx 10^(-2) kJ mol^(-1) (Delta_(r)S)_(1200K) =- 3.0 xx10^(-2) kJ mol^(-1) Predict the direction of spontaneity of the reaction at 300K and 1200K . also calculated log_(10)K_(p) at 300K and 1200K .

Calculate delta H° for the reaction , CaC_2(s) + 2H_2O(l) rarr Ca(OH)_2(s) + C_2H_2(g) , delta H°_(f(CaC_2)) = -62.0 kj/mol , delta H°_(f(H_2O)) = -286.0 kj/mol , delta H°_(f(CaOH_2)) = -986.0 kj/mol , delta H°_(f(C_2H_2)) = -227.0 kj/mol ,

Calculate the resonance energy of toluene (use Kekule structure from the following data C_(7)H_(8)(l) +9O_(2)(g) rarr 7CO_(2)(g) +4H_(2)O(l)+ DeltaH, DeltaH^(Theta) =- 3910 kJ mol^(-1) C_(7)H_(8)(l) rarr C_(7)H_(8)(g), DeltaH^(Theta) = 38.1 kJ mol^(-1) Delta_(f)H^(Theta) (water) =- 285.8 kJ mol^(-1) Delta_(f)H^(Theta) [CO_(2)(g)] =- 393.5 kJ mol^(-1) Heat of atomisation of H_(2)(g) = 436.0 kJ mol^(-1) Heat of sublimation of C(g) = 715.0 kJ mol^(-1) Bond energies of C-H, C-C , and C=C are 413.0, 345.6 , and 610.0 kJ mol^(-1) .

For the reaction : C_(2)H_(5)OH(l)+3O_(2)(g)rarr2CO_(2)(g)+3H_(2)O(g) if Delta U^(@)= -1373 kJ mol^(-1) at 298 K . Calculate Delta H^(@)

Calculate K_(sp) for AgCI . Given: Delta_(f)H^(Θ) Ag^(o+) = 25.3 kcal mol^(-1) Delta_(f)H^(Θ) C1^(Θ) =- 40.0 kcal mol^(-1) Delta_(f)H^(Θ) AgC1=- 30.36 kcal mol^(-1) S^(Θ) Ag^(o+), S^(Θ) C1^(Θ) , and S^(Θ) AgC1 are 17.7, 13.2 and 23.0 cal mol^(-1)

Predict the standard reaction enthalpy of 2NO_(2)(g)rarrN_(2)O_(4)(g) at 100^(@)C . Delta H^(@) at 25^(@)C is -57.2 kj.mol^(-1)C_(p)(NO_(2))=37.2j.mol^(-1)K^(-1)C_(p)(N_(2)O_(4))=77.28 J. mol^(-1)k^(-1)