For the reaction `2NH_(3) hArr N_(2) + 3H_(2)` equilibrium constant at `25^(@)`C and `400^(@)`C and 3.5 and 35 respcctively. This means that the forward reaction is:

For the formation of NH_(3) from N_(2) and H_(2) at 500 K, the concentration of N_(2), H_(2) and NH_(3) at equilibrium are 1. 5xx10^(-2) M and 1.2xx10^(-2)M, respectively. The equilibrium constant for the reverse reaction is

For the formation of NH_3 from H_2 at 500 K, The concentration of N_2, H_2 and NH_3 at equilibrium are 1.5xx10^(-2) M , 3.0 x 10^(-2) M and 1.2 xx 10^(-2) M , respectively. The equilibrium constant for the reverse reaction is

For the reaction, N_(2) + 3H_(2) hArr 2NH_(3) in a vessel, equal moles of N_(2) and H_(2) are mixed to attain equilibrium.

K_(p) for the reaction N_(2) + 3H_(2) hArr 2NH_(3) , is 1.6 xx 10^(-4) atm^(-2) at 400^(@) C. What will be K_(p) at 500^(@) C ? Heat of reaction in this temperature range is-25.14 Kcal.

The equilibrium constant (K_(C)) for the reaction HA +B hArr BH^(+) + A is 100. If the rate constant for the forward reaction is 10^(5) , rate constant for the reverse reaction is

Mass action ratio or reaction quotient Q for a reaction can be calculated using the law of mass action A(g)+B(g) harr C(g) + D(g) Q=([C][D])/([A][B]) . The value of Q decides whether the reaction is at equilibrium or not. At equilibrium, Q = K. For non equilibrium process, Q ne K . When Q gt K , reaction will favour backward direction and when Q lt K , it will favour forward direction. For the reaction : 2A + B harr 3C at 298 K, K_c = 49 A 3L vessel contains 2,1 and 3 moles of A, B and C respectively. The reaction at the same temperature: