Consider the equilibrium `A(g) hArr 2B (g) +3C(g) "at" 25^@C`. When A is loaded into a cylinder at 10.0 atm and the system is allowed to come an equilibrium the , final pressure is found to be 15.76 atm, what is standard Gibbs eneergy change for the reaction ?

If the equilibrium constant of a reaction is 2×10^3 at 25°C then the standard Gibbs free energy change for the reaction will be

For the reaction NH_(4)HS(g) hArr NH_(3)(g)+H_(2)S(g) in a closed flask, the equilibrium pressure is P atm. The standard free energy of the reaction would be:

For the equilibrium NH_2CONH_4(s) hArr 2NH_3(g) +CO_2(g) P_(CO_2)= 1 atm at 100^@C . What will be the equilibrium constant at 100^@C in atm.

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.

Equilibrium constant for the reaction: H_(2)(g) +I_(2) (g) hArr 2HI(g) is K_(c) = 50 at 25^(@)C The standard Gibbs free enegry change for the reaction will be:

The reaction, 2A(g) + B(g)hArr3C(g) + D(g) is begun with the concentration of A and B both at an intial value of 1.00 M. When equilibrium is reached, the concentration of D is measured and found to be 0.25 M. The value for the equilibrium constant for this reaction is given by the expression:

In the reaction AB(g) hArr A(g) + B(g) at 30^(@)C, k_(p) for the dissociation equilibrium is 2.56xx10^(-2) atm . If the total pressure at equilibrium is 1 atm, then the percentage dissociation of AB is