The equilibrium:
`P_(4)(g)+6Cl_(2)(g) hArr 4PCl_(3)(g)`
is attained by mixing equal moles of `P_(4)` and `Cl_(2)` in an evacuated vessel. Then at equilibrium:

The equilibrium, P_(4)(s) + 6 Cl_(2)(g) rarr 4PCl_(3) attained by mixing equal moles of P_(4) "and" Cl_(2) in a evacuated vessel. Then at equilibrium

The equilibrium A(g) +4B(g) hArr AB_4(g) is attained by mixing equal moles of A and B in a one litre vessel Then at equilibrium

The equilibrium A(g) +4B(g) hArr AB_4(g) is attained by mixing equal moles of A and B in a one litre vessel Then at equilibrium

The equilibrium A_((g))+4B_((g))hArrAB_(4(g)) is attained by mixing equal moles of A and B in a one litre vessel. Then at moles of A and B in a one litre vessel. Then at equilibrium

4 mole of Sl_(2)Cl_(4)(g) is introduced innto a 10L vessel. The following equilibrium was established S_(2)Cl_(4)(g)hArr2SCl_(2)(g) at equilibrium 0.2 mol of S_(2)Cl_(4) was present in the vessel. The value of equilibrium constant is.

4 mole of Sl_(2)Cl_(4)(g) is introduced innto a 10L vessel. The following equilibrium was established S_(2)Cl_(4)(g)hArr2SCl_(2)(g) at equilibrium 0.2 mol of S_(2)Cl_(4) was present in the vessel. The value of equilibrium constant is.

For the equilibrium 2NO(g)+Cl_(2)(g)hArr 2NOCl(g) K_(p) is related to K_(c) by the reaction