`N_(2)+3H_(2)rarr2NH_(3)`. 1 mol `N_(2)` and 4 mol `H_(2)` are taken in 15L flask at `27^(@)C` After cmomplete conversion of `N_(2)` into `NH_(3),5L` of `H_(2)O` is added pressure set up in the flask is:

N_(2)+3H_(2)rarr2NH_(3) . 1 mol N_(2) and 4 mol H_(2) are taken in 15L flask at 27^(@)C After complete conversion of N_(2) into NH_(3),5L of H_(2)O is added. pressure set up in the flask is:

2 "mole" N_(2) and 3 "mole" H_(2) gas are allowed to react in a 20 L flask at 400 K and after complete conversion of H_(2) into NH_(3) . 10 L H_(2)O was added and temperature reduced to 300 K . Pressure of the gas after reaction is : N_(2)+3H_(2)to2NH_(3)

2 "mole" N_(2) and 3 "mole" H_(2) gas are allowed to react in a 20 L flask at 400 K and after complete conversion of H_(2) into NH_(3) . 10 L H_(2)O was added and temperature reduced to 300 K . Pressure of the gas after reaction is : N_(2)+3H_(2)to2NH_(3)

2 "mole" N_(2) and 3 "mole" H_(2) gas are allowed to react in a 20 L flask at 400 K and after complete conversion of H_(2) into NH_(3) . 10 L H_(2)O was added and temperature reduced to 300 K . Pressure of the gas after reaction is : N_(2)+3H_(2)to2NH_(3)

For N_(2)+3H_(2)hArr 2NH_(3) , 1 mole N_(2) and 3 mol H_(2) are at 4 atm. Equilibrium pressure is found to be 3 atm. Hence, K_(p) is

N_(2) + 3H_(2)hArr2NH_(3) 1mole N_(2) and 3 moles H_(2) are present at start in 1 L flask. At equilibrium NH_(3) formed required 100 mL of 5 M HC1 for neutralisation hence K_(c) is

1 mol of N_(2) and 2 mol of H_(2) are allowed to react in a 1 dm^(3) vessel. At equilibrium, 0.8 mol of NH_(3) is formed. The concentration of H_(2) in the vessel is

1 mol of N_(2) and 2 mol of H_(2) are allowed to react in a 1 dm^(3) vessel. At equilibrium, 0.8 mol of NH_(3) is formed. The concentration of H_(2) in the vessel is

A 1.0 L flask contains 2.0 g of N_(2), 0.4 g H_(2) and 9.0 of O_(2) at 27^(@)C . What is the pressure in the flask?