`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

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

For a reaction, 2SO_(2(g))+O_(2(g))hArr2SO_(3(g)) , 1.5 moles of SO_(2) and 1 mole of O_(2) are taken in a 2 L vessel. At equilibrium the concentration of SO_(3) was found to be 0.35 mol L^(-1) The K_(c) for the reaction would be

If 0.2 mol of H_(2)(g) and 2.0 mol of S(s) are mixed in a 1.0 L vessel at 90^(@)C , the partial pressure of H_(2)S(g) formed according to the reaction H_(2)(g)+S(s)hArr H_(2)S(g),K_(p) at 363K=6.78xx10^(-2) would be

One mole of X_(2) is mixed with one mole of Y_(2) in a flask of volume 1 litre . If at equilibrium 0.5 mole of Y_(2) are obtained. Then find out K_(P) for reaction X_(2(g))+Y_(2(g))hArr2XY_(g)

For the reaction, A(g)+2B(g)hArr2C(g) one mole of A and 1.5 mol of B are taken in a 2.0 L vessel. At equilibrium, the concentration of C was found to be 0.35 M. The equilibrium constant (K_(c)) of the reaction would be

3 mole of SO_(3)(g) are taken in 8.0 L container at 800^(@)C . At equilibrium, 0.58 mol of O_(2)(g) are formed. Find the value of K_(c) for 2SO_(2)(g)+O_(2)(g) hArr 2SO_(3)(g)

In the reaction X(g)+Y(g)hArr2Z(g),2 mole of X,1 mole of Y and 1 mole of Z are placed in a 10 litre vessel and allowed to reach equilibrium .If final concentration of Z is 0.2 M , then K_(c) for the given reaction is :

Calculate the precentage dissociation of H_(2)S(g) if 0.1 mol of H_(2)S is kept in a 0.5 L vessel at 1000 K . The value of K_(c ) for the reaction 2H_(2)ShArr2H_(2)(g)+S_(2)(g) is 1.0xx10^(-7).

A mixture of 1.57 mol of N_(2), 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20 L reaction vessel at 500 K . At this temperature, the equilibrium constant K_(c ) for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium? If not, what is the direction of the net reaction?

A mixture of 1.57 mol of N_(2), 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20 L reaction vessel at 500 K . At this temperature, the equilibrium constant K_(c ) for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium? If not, what is the direction of the net reaction?