`1` mol of `XY(g)` and `0.2` mol of `Y(g)` are mixed in `1` L vessel. At equilibrium, `0.6` mol of `Y(g)` is present. The value of `K` for the reaction
`XY(g)hArrX(g)+Y(g)` is

1 mol of of XY_(g) and 0.2 mol of Y_(g) are mixed in 1L vessel. At equilibrium 0.6 mol of Y _(g) is present .The value of K for the reaction :- XY(g) hArr X(g)+Y(g) is

Initially, 0.8 mole of PCl_(5) and 0.2 mol of PCl_(30 are mixed in one litre vessel. At equilibrium, 0.4 mol of PCl_(3) is present. The value of K_(c ) for the reaction PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g) would be

Initially, 0.8 mole of PCl_(5) and 0.2 mol of PCl_(3 are mixed in one litre vessel. At equilibrium, 0.4 mol of PCl_(3) is present. The value of K_(c ) for the reaction PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g) would be

2 mol of N_(2) is mixed with 6 mol of H_(2) in a closed vessel of 1L capacity. If 50% of N_(2) is converted into NH_(3) at equilibrium, the value of K_(C ) for the reaction N_(2)(g0+3H_(2)(g)hArr 2NH_(3)(g) is

3 mols of A and 1 mol of B are mixed in a 1L container. The reaction taking place is A(g)+B(g) iff 2C(g) . If 1.5 mol of C is formed at equilibrium, the K_(c) of the reaction is

At 20^(@)C,0.258mol" "A(g) and 0.592 mol B(g) are mixed in a closed vessel of 5L capacity to conduct the following reaction: A(g)+2B(g)hArr C(g) . If 0.035 mol C(g) remains in the equilibrium mixture, then determine the partial pressure of each constituent at equilibrium.

8 mol of gas AB_(3) are introduced into a 1.0 dm^(3) vessel. It dissociates as 2AB_(3)(g) hArr A_(2)(g)+3B_(2)(g) At equilibrium, 2 mol of A_(2) is found to be present. The equilibrium constant for the reaction is

8 mol of gas AB_(3) are introduced into a 1.0 dm^(3) vessel. It dissociates as 2AB_(3)(g) hArr A_(2)(g)+3B_(2)(g) At equilibrium, 2 mol of A_(2) is found to be present. The equilibrium constant for the reaction is

The reaction A(g)+4B(g)hArr2C(g)+3D(g) is carried out in a closed vessel of volume 2L by taking 3 mol of A(g) and 4 mol of B(g ). At equilibrium, if the amount of C(g) be 1 mol. then K_c for the reaction is-