In a closed system: `A(s) hArr 2B(g)+3C(g)`, if the partial pressure of C is doubled at equillibrium, then partial pressure of B will be :

Temperature pressure and molar concentration are the three factors which can disturb the equilibrium in a reversible reaction. Their effect is governed by Le Chatelier's principle . Whereas high concentration of the reactants always favours the formation of the products irrespective of its nature the effect of temperature and pressure depends upon the nature of the reaction . pressure does not disturb the equilibrium point in a reaction in which the reactants and products have same number of moles in the gaseous state. In a closed system A (s) hArr 2B(g) +3C(g) if partical pressure of C is doubled then partial pressure of B will be :

In a closed system : A(s)hArr 2B(g)+3C , if the partial pressure of C is doubled, then partial pressure of B will be

A sample of pure NO_2 gas heated to 1000 K decomposes : 2NO_2(g) hArr 2NO(g)+O_(2)(g) The equilibrium constant K_P is 100 atm. Analysis shows that the partial pressure of O_2 is 0.25 atm. At equilibrium.The partial pressure of NO_2 at equilibrium is:

For a certain A(g)to B(g) at equillibrium . The parital pressure of B is found to be one fourth of the partial pressure of A. The value of DeltaG^(@) of the reaction A to B is:

For the reaction at 127^@ C N_2(g) + 3H_2(g) hArr 2NH_3(g) the partial pressures of N_2 and H_2 are 0.80 and 0.40 atm respectively at equilibrium. The total pressure of the system is 2.80 atm. Calculate K_p and K_c for the reaction.

For the reaction A_(2)(g) + 2B_(2)hArr2C_(2)(g) the partial pressure of A_(2) and B_(2) at equilibrium are 0.80 atm and 0.40 atm respectively.The pressure of the system is 2.80 atm. The equilibrium constant K_(p) will be