28g of `N_2` and 6g of `H_2` were mixed. At equilibrium 17g of `NH_3` was produced. The masses of `N_2` and `H_2` at equilibrium are respectively

H_2(g)+l_2(g)iff2Hl(g) , This reaction is carried in a 2 litre flask taking 0.4 mol H_2 and 0.4 mol l_2 . At equilibrium if 0.5 mol Hl is produced then calculate the value of equilibrium constant K_c .

1 mole N_2 and 3 moles of H_2 are taken in a 4 litre flask. If 0.25% of N_2 is converted to NH_3 at equilibrium and the reaction is N_2(g)+3H_2(g)iff2NH_3(g) . Then calculate the value of K_c under that condition. Prove that for the reaction aA_2(g)+bB_2(g)iffcAB(g) the value of the ratio K_p/K_c is 1 when a+b=c.

A mixture containing N_2 and H_2 in a mole ratio 1 : 3 is allowed to attain equilibrium when 50% of the mixture has reacted. If P is the pressure at equilibrium, then the partial pressure of NH_3 formed is

Two moles of HI were heated in a scaled tube at 440^@C until the equilibrium was reached. HI was found to be 22% dissociated. Calculate equilibrium constant for the reaction 2HI(g) rarr H_2(g) + I_2(g) .

2 moles of N_2 and 5 moles of H_2 are mixed in a one litre flask. If 75% of N_2 is converted into ammonia by the reaction N_2(g) + 3H_2(g) iff 2NH_3(g) , then the total number of moles of gas at equilibrium Is :

For the equilibrium N_2 (g) + O_2(g) = 2 NO (g)

At 986^(@) C the value of equilibrium constant (K_c) for the reaction, CO(g)+H_2O(g)toCO_2(g)+H_2(g) is 0.63At this temperature, 1 mol of H_2O (g) is allowed to react with 3 mol of CO(g). This results in the above equilibrium in which the observed pressure is 2.0 atm. Find the number of moles of H_2 (g) produced at equilibrium and the partial pressure of each gas

At 300K , the partial pressures of N_2O_4 (g) and NO_2 (g) in an equilibrium mixture of the reaction: N_2O_4(g)

The following concentrations were obtained for the formation of NH_3 from N_2 and H_2 at equilibrium at 500K. [N_2] = 1.5 xx 10^-2M. [H_2] = 3.0 xx10^-2 M and [NH_3] =1.2 xx 10^-2 M . Calculate equilibrium constant.