`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.

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

50.0 kg of N_(2) (g) and 10.0 kg of H_(2) (g) are mixed, to produce NH_(3)(g) . Calculate the NH_(3)(g) . Formed. Identify the limiting reagent in the production of NH_(3) in this situation.

50.0 kg of N_(2)(g) and 10.0 kg of H_(2)(g) are mixed to produce NH_(3)(g) . Calculate the NH_(3)(g) formed. Identify the limiting reagent in the production of NH_(3) in this situation.

50.0 kg of N_(2)(g) and 10.0 kg of H_(2)(g) are mixed to produce NH_(2)(g) . Calculate the NH_(2)(g) formed. Identify the limiting reagent in the production of NH_(3) in this situation.

50.0 kg of N_2 (g) and 10.0 kg of Hydrogen (g) are mixed to produce NH_3 (g). Calculate the amount of NH_3 (g) formed. Identify the limiting reagent in the production Of NH_3 in this situation. —

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