For the equilibrium `2NO_2(g) ⇌ N_2O_4(g) +14.6 kcal`An increase of temperature will:

40% of a mixture of 0.2 mole of N_2 and o.6 mole of H_2 react to give NH_3 according to the equation: N_ 2 ( g ) + 3 H_ 2 ( g ) ⇔ 2 N H_ 3 (g) at constant temperature and pressure. Then what is the ratio of the final volume to the initial volume of gases ?

The standard heat of formation of NO_2(g) amd N_2O_4(g) are 8.0 2.0 kcal mol^-1 respectively. The heat of dimerization of NO_2 in kcal is:

For the reaction : C_2H_4(g)+5O_2(g)→3CO_2(g)+4H_2O(l) at constant temperature. triangle H - triangle U is:

For the reaction 3H_2(g) + N_2(g) rarr 2NH_3(g) . Compute and equate the reaction rates.

The decomposition of N_(2) O_(5) according to the equation, 2N_(2) O_(5) (g) to 4NO_(2) (g) + O_(2) (g) is a first order reaction. After 30 minutes from the start of the decomposition in a closed vessel, the total pressure developed is found to be 284.5 mm of Hg and on complete decomposition, the total pressure is 584.5 mm of Hg. Calculate the rate constant of the reactions.

In the reaction, N_2(g) +3H_2(g) hArr2NH_3(g) increase in H_2 concentration equilibrium:

State Le Chatellier principle and explain its application to the following reaction at equilibrium : N_2(g) + 3 H_2(g) harr 2 NH_3 + 22.4 kcal .

The data given below is for the reaction, 2N_(2) O_(g) (g) to 4NO_(2) (g) + O_(2) (g) Determine for the above reaction, rate law

The data given below is for the reaction, 2N_(2) O_(g) (g) to 4NO_(2) (g) + O_(2) (g) Determine for the above reaction, rate constant