Calculate equilibrium constant (in multiples of `10^(-80)`) when sodium reduces Aluminium oxide to aluminium at 298 K. `Delta G^(@)_(f)` of `Na_(2)O_(3(s))` at `298 K = -377 KJ "mole"^(-1)` and `Delta G^(@)_(f)` of `Al_(2)O_(3)` at `298K = -1582 KJ "mole"^(-1)`)

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)

The equilibrium constant for the following general reaction is 10^(@). Calculate E^(@) for the cell at 298 K. 2X_2(s) + 3Y^(2+)(aq) to 2X_(2)^(3+)(aq) + 3Y (s)

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 standard internal change in multiples of -10^(2)KJ for the reaction OF_(2(g)) + H_(2)O_((g)) rarr O_(2(g)) + 2HF_((g)) at 298K. The standard enthalpies of formation of OF_(2(g)), H_(2)O_((g)), HF_((g)) " are " +20, -250 and -270KJ "mole"^(-1)

Calculate the pH at which the following conversion (reacton ) will be at equilibrium in basic medium I_(2(s)) hArr I_((aq))^(-) + IO_(3(aq))^(-) . When the equilibrium concentrations at 300 K are [I^(-)] = 0.10 and [IO_(3)^(-)] = 0.10M Given that Delta G_(f)^(0) (I^(-)aq) = -50 kJ/mole, Delta G_(f)^(0) (IO_(3)^(-), aq) = -123.5 kJ//"mole", Delta G_(f)^(0) (H_(2)O, l) = - 233 kJ/mole, DeltaG_(f)^(0) (OH^(-), aq) = - 150 kJ/mole, Ideal gas constant = R = (25)/(3)J "mole"^(-1) K^(-1) , log e = 2.3,

Calculate the free energy change in kJ when 1 mole of NaCl is dissolved in water at 298 K, Given a) U of NaCl (U = lattice energy) = 778 kJ "mole"^(-1) b) Hydration energy of NaCl = -774.3 kJ "mole"^(-1) (c) Entropy change at 298K = 43 "mole"^(-1)

The value of Delta_fG^(Theta) for formation of Cr_2 O_3 is – 540 kJ "mol"^(-1) and that of Al_2 O_3 is – 827 kJ "mol"^(-1) . Is the reduction of Cr_2 O_3 possible with Al ?