For the equilibrium `AB(g) hArr A(g)+B(g)` at a given temperature, the pressure at which one-third of AB is dissociated is numerically equal to

For the equilibrium AB(g) hArr A(g)+B(g) . K_(p) is equal to four times the total pressure. Calculate the number moles of A formed if one mol of AB is taken initially.

For the reaction CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) at a given temperature, the equilibrium amount of CO_(2)(g) can be increased by

2 is the equilibrium constant for the reaction A_(2)+B_(2)hArr 2AB at a given temperature. What is the degree of dissociation for A_(2)" or "B_(2)

For the reaction 3A(g)+B(g) hArr 2C(g) at a given temperature , K_c=9.0 .What must be the volume of the flask, if a mixture of 2.0 mol each of A, B and C exist in equilibrium ?

consider the given reaction, 3A(g) + B(g) hArr 2C(g) at a given temperature if a mixture of 2 mol each of A, B and C exist at equilibrium and K_c =9 then volume of the flask will be

In the equilibrium, AB(s) rarr A(g) + B(g) , if the equilibrium concentration of A is doubled, the equilibrium concentration of B would become

K_(p) for the reaction PCl_(5)(g)ghArrPCl_(3)(g)+Cl_(2)(g) at 250^(@)C is 0.82 . Calculate the degree of dissociation at given temperature under a total pressure of 5 atm . What will be the degree of dissociation if the equilibrium pressure is 10 atm , at same temperature.

for the reaction 2A_((g)) hArr B_((g)) + 3C_((g)) , at a given temperature, K_(c) = 16. What must be the volume of the falsk, If a mixture of 2 mole cach A, B and C exist in equilibrium ?

Attainment of the equilibrium A(g)hArr2C(g)+B(g) gave the following graph . Find the correct option . (% dissociation=Fration dissoiatedxx100)

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