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

28g of N_2 and 6g of H_2 were mixed. At equilibrium 17g of NH_3 was formed. The weight of N_2 and H_2 at equilibrium are respectively

20.0 kg of N_(2)(g) and 3.0 kg of H_(2)(g) are mixed to produce NH_(3)(g) . The amount of NH_(3)(g) formed is

50.0 kg of N_(2) (g) and 10 g of H_(2) (g) are mixed to produce NH_(3) (g) . Calculate the NH_(3) (g) formed. Identify the limiting reagent.

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))

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)

N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) For the reaction intially the mole ratio was 1:3 of N_(2):H_(2) .At equilibrium 50% of each has reacted .If the equilibrium pressure is P, the parial pressure of NH_(3) at equilibrium is :