28 g of `N_(2)` and 6 g of `H_(2)` were kept at `400^(@)C` in 1 litre vessel, the equilibrium mixture contained `27.54` g of `NH_(3)`. The approximate value of `K_(c)` for the above reaction can be `("in mole"^(-2) "litre"^(2))`

28 g N_2 and 6.0 g of H_2 are heated over catayst in a closed one litre flask of 450^@C . The entire equilibrium mixture required 500 mL of 1.0 MH_2SO_4 for neutralisation. The value of K_c for the reaction N_2(g)+3H_2(g)hArr2NH_3(g) is

2 mol of N_(2) is mixed with 6 mol of H_(2) in a closed vessel of one litre capacity. If 50% N_(2) is converted into NH_(3) at equilibrium, the value of K_(c) for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g)

28 g of N_(2) and 6 g of H_(2) were mixed. At equilibrium 17 g NH_(3) was produced. The weight of N_(2) and H_(2) at equilibrium are respectively

At 700 K , the equilibrium constant , K_p for the reaction 2SO_3(g) hArr 2SO_2(g) +O_2 (g) is 1.8 xx10^(-3) atm. The value of K_c for the above reaction at the same temperature in moles per litre would be

When 3.00 mole of A and 1.00 mole of B are mixed in a 1,00 litre vessel , the following reaction takes place A(g) +B(g) hArr 2C(g) the equilibrium mixture contains 0.5 mole of C. What is the value of equilibrium constant for the reaction ?