At a definite temperature, the equilibrium constant for a reaction, `A+BhArr2C`, was found to be 81. Starting with 1 mole A and 1 mole B, the mole fraction of C at equilibrium is :

In an experiment the equilibrium constant for the reaction A+BhArr C+D is K_(C) when the initial concentration of A and B each is 0.1 mole. Under similar conditions in an another experiment if the initial concentration of A and B are taken to be 2 and 3 moles respectively then the value of equilibrium constant will be

In an experiment the equilibrium constant for the reaction A+BhArr C+D is K_(C) when the initial concentration of A and B each is 0.1 mole. Under similar conditions in an another experiment if the initial concentration of A and B are taken to be 2 and 3 moles respectively then the value of equilibrium constant will be

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.

If 1 mole of acetic acid and 1 mole of ethyl alcohol are mixed together and the reaction proceeds to the equilibrium, the concentration of acetic acid and water are found to be 1/3 and 2/3 mole respectively. Calculate the equilibrium constant.

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.

1.1 mole of A and 2.2 moles of B reach an cquilibrium in I lit container according to the reaction. A + 2B hArr 2C + D. If at equilibrium 0.1 mole of D is present, the equilibrium constant is:

1.1 mole of A and 2.2 moles of B reach an cquilibrium in I lit container according to the reaction. A + 2B hArr 2C + D. If at equilibrium 0.1 mole of D is present, the equilibrium constant is: