Calculate the resonance energy of` N_2O` from the following data `Delta_1 H^0 of N_2O = 82 kJ mol^(-1)` for the reaction `N_2(g) + 1/2 O_2 (g) rarr N_2O (g)` Bond energy of `N=N, N=N, O=O` and `N=0` bonds are 946,418,498 and `607 kJ mol^(-1)` respectively.

For the equilibrium N_2 (g) + O_2(g) = 2 NO (g)

Discuss the rate of the reaction 2N_(2)O_(5(g)) rarr 4NO_(2(g))+O_(2(g))

Give the equations for the preparation of N_(2)O from the following: NH_(3), O_(2), Pt and H_(2)O .

N_2(g) + 2O_2 (g) rarr 2NO_2 (g) + X kJ 2NO (g) + O_2(g) rarr 2NO_2 (g) + Y kJ the enthalpy of.formation of NO is

Calculate the DeltaG^0 for the reaction N_2(g) + O_2(g) * 2NO(g) Given DeltaH^0 =180.5 K.J , and DeltaS^0 = 15 J at 25^@C .

Write the rate law of 2N_(2)O_(5(g))rarr 4NO_(2(g))+O_(2(g)) reaction.

Assertion DeltaH and DeltaE are almost the same for the reaction, N_2(g) + O_2(g) iff 2NO(g) Reason All reactants and products are gases.

Find the relation betweenn K_(p)&K_(c) for the given reactions: (1)/(2)N_(2)(g)+O_(2)(g)hArrNO_(2)(g)

Standard enthalpy of combustion of CH_(4)(g) " is " 802.8 " kJ mol"^(-1) . If the bond dissociation energies of C-H, O=O and O-H bonds are 416.2, 493.7 and 464.4 " kJ mol"^(-1) respectively then calculate the bond dissociation energy of C=O bond.

Calculate DeltaG^(0) for the reaction H_(2)(g)+(1)/(2)O_(2)(g)toH_(2)O(l) at 298K. Given, at 298K DeltaH_(f)^(0) for H_(2)O(l) is -286 kJ *mol^(-1) and the molar entropies (S^(0)) for H_(2)(g),O_(2)(g) and H_(2)O(l) are 130.7, 205.1 and 69.9 J*K^(-1)*mol^(-1) respectively.