As per law of mass action, for `NH_(4) `HS(s) `hArr NH_(3)(g) + H_(2) S(g)` ratio of rate constants of forward `(K_(f))` & backword `(K_(b))` reactions at equilibrium equals ot

In the equilibrium NH_(4) HS_(s) hArr NH_(3(g)) + H_(2) S_((g)) . the forward reaction can be favoured by

Unit of K_p for NH_4COONH_(2(s)) harr 2NH_(3(g))+ CO_(2(g)) is

For the reaction PCl_(5(g)) hArr PCl_(3(g)) + Cl_(2(g)) the forward reaction at constant temperature is favoured by

For the following reaction NH_(4)HS_((s)) harr NH_(3(g))+H_(2)S_((g)) the total pressure at equilibrium is 30 atm. The value of K_(P) is

In the equilibrium NH_(4)HS_((s))

For the equilibrium reaction, 3Fe_((s)) + 4H_(2) O_((g)) hArr Fe_(3)O_(4(s)) + 4 H_(2(g)) the relation between K_(p) and K_(c) is

Peqfor NH_(4)COONH_(2(s)) harr 2NH_(3(g))+ CO_(2(g)) at certain temperature is 0.9 atm. Then, partial pressure of Ammonia at equilibrium (in atm)

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. In a reaction mixture containing H_2 , N_2 and NH_3 at partial pressure of 2 atm, and 3 atm respectively, the value of K_p at 725 K is 4.28 xx 10^(-5) atm^(-2) . In which direction the net reaction will go ? N_(2(g)) + 3H_(2(g)) harr 2NH_(3(g))

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: