In a reaction at equilibrium, `'x'` mole of reactant `A` decompose to give `1 molar` of `C` and `D`. It has been found that the fraction of `A` decomposed at equilibrium is independent of initial concentration of `A`. Calculate `x`.

In a reaction at equilibrium, X moles of the reactant A decomposes to give 1 mole each of C and D. It has been found that the fraction of A decomposed at equilibrium is independent of initial concentration of A. Calculate X.

In a reaction at equilibrium, 'x' mole of reactant A decompose to give 1 molar of C and D . It has been found that the fraction of A decomposed at equilibrium is independent of initial concentration of A . Find the value of x .

In a reaction at equilibrium, x' mole of the reactant 'A' decompose to give I mole of C and D. It has been found that the fraction of A decomposed at equilibrium is independent of intial concentration of A. Find the value of x.

In a reaction at equillibrium X mole of the reactant A decompose to give 1 mole each of C and D. if the fraction of A decomposed at equillibrium is independent of initial concentration of A then what will be the value pf X ?

In a gaseous reaction at equilibrium , 'n' mole of reactant 'A' decompose to give 1 mole each of C and D.It has been found that degree of dissociation of A at equilibrium is independent of total pressure.Value of 'n' is :

In a gaseous reaction at equilibrium , 'n' mole of reactant 'A' decompose to give 1 mole each of C and D.It has been found that degree of dissociation of A at equilibrium is independent of total pressure.Value of 'n' is :

Assertion : The equilibrium constant for the reverse reaction is equal to the inverse of the equilibrium constant for the forward reaction . Reason : The value of equilibrium constant is independent of initial concentrations of the reactants and products.

Assertion : The equilibrium constant for the reverse reaction is equal to the inverse of the equilibrium constant for the forward reaction . Reason : The value of equilibrium constant is independent of initial concentrations of the reactants and products.