If the equilibrium constants of following reactions are `2A hArr B` is `K_(1)` and `B hArr2A` is `K_(2)`, then

What is the value of the equilibrium constant for the following reaction at 400 K ? 2NOCl(g) hArr 2NO(g) + Cl_(2)(g) Delta H^(@) = 77.5 kJ mol^(-1), R = 8.3124 J mol^(-1) K^(-1), Delta S = 135 J K^(-1) mol^(-1) .

The following equilibrium are given : N_(2)+3H_(2)hArr 2NH_(3):K_(1) N_(2)+O_(2)hArr 2NO : K_(2) H_(2)+(1)/(2)O_(2)hArr H_(2)O : K_(3) The equilibrium constant of the reaction : 2NH_(3)+(5)/(2)O_(2)hArr 2NO+3H_(2)O in terms of K_(1), K_(2) and K_(3) is :

At temperature T_(1) , the equilibrium constant of eaction is K_(1) . At a higher temperature T_(2),K_(2) is 10% of K_(1) . Predict whether the equilibrium is endothermic or exothermic.

The equilibrium constant, K_(p) for the reaction : A hArr 2B is related to degree of dissociation alpha of A and total pressure P as :

The equilibrium constant, K_(c ) for the reaction : H_(2)+I_(2) hArr 2HI at 700 K is 49. What is the equilibrium constant for the reaction : HI hArr (1)/(2)H_(2)+(1)/(2)I_(2) at the same temperature ?

K_(a_(1)), K_(a_(2)) and K_(a_(3)) are the respective ionisation constants for the following reactions. H_(2)S hArr H^(+)+HS^(-) HS^(-)hArr H^(+)+S^(2-) H_(2)S hArr 2H^(+)+S^(2-) The correct relationship between K_(a_(1)), K_(a_(2)) and K_(a_(3)) is

The equilibrium constant for the reaction N_(2)(g) + O_(2) hArr 2NO(g) is 4 xx 10^(-4) at 2000 K. In presence of a catalyst the equilibrium is attained ten times faster. Therefore the equilibrium constant in presence of catalyst at 2000 K is