5 litre vessel contains 2 moles of each of gases A and B at equilibrium. If 1 mole each of A and B are removed. Calculate `K_(C)` for the reaction `A(g) iffB(g)`

A 1-litre vessel contains 2 moles each of gases "A,B,C and D at equilibrium. If 1 mole each of A and B are removed K_(C) for A+B harr C+D will be a) 4 b) 1 c) (1)/(4) d) 2

A one litre vessel contains 3 moles each of gases A, B, C and D at equilibrium. If one mole each of A and B are removed K_(C) for A(g)+B(g)hArrC(g)+D(g) will be

In a vessel of 5L,26 moles of A and 4 moles of B were placed. At equilibrium 1 mole of C was present. The K_(C) for the reaction : A+2bhArrC is

In 500 ml capacity vessel CO and Cl_(2) are mixed to form COCl_(2) . At equilibrium, it contains 0.2 moles of COCl_(2) and 0.1 mole of each of CO and Cl_(2) , The equilibrium constant K_(C) for the reaction CO(g)+Cl(g)hArrCOCl_(2)(g) is

For the reaction "A+B rarr 3C" at 25^(0)C a 3 litre vessel contains "1,2,4" moles of A,B" and "C" respectively.Predict the direction of reaction if K_(c) for the reaction is 10 (A) Forward (B) Backward (C) Reaction stops (D) It is already in equilibrium

For reaction A(g) + B(g) we start with 2 moles of A and B each. At equilibrium 0.8 moles of AB is formed. Then how much of A changes to AB

At 87^(@)C , the following equilibrium is established H_(2) (g)+S(s)hArrH_(2)S(s)(g), K_(p)=7xx10^(-2) If 0.50 mole of hydrogen and 1.0 mole of sulphuur are heated to 87^(@)C and 2.0 atm .the equilibrium gases mixture contains 40% chlorine by volume. Calculate K_(p) at 247^(@)C for the reaction PCl_(5)(g)hArrPCl_(3)(G)+Cl_(2)(g)

In the decomposition reaction AB_(5)(g)hArrAB_(3)(g)+B_(2)(g) , at equilibrium in a 10 litre closed vessel at 227^(@)C , 2 moles of AB_(3) , 5 moles of B_(2) and 4 moles of AB_(5) , are present. The equilibrium contstant K_(c) for the formation of AB_(5)(g) is

1 mole of 'A' 1.5 mole of 'B' and 2 mole of 'C' are taken in a vessel of volume one litre. At equilibrium concentration of C is 0.5 mole /L .Equilibrium constant for the reaction , A_((g))+B_((g) hArr C_((g)) is