If a mixture of `3` mol of `H_(2)` and `1 "mole"` of `N_(2)` is completely converted into `NH_(3)`, what would be the ratio of the initial and final volume at same temperature and pressure?

40% of a mixture of 0.2 mol of N_(2) and 0.6 mol of H_(2) reacts to give NH_(3) according to the equation: N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) at constant temperature and pressure. Then the ratio of the final volume to the initial volume of gases are

2NH_(3) to N_(2) + 3H_(2) Find moles of H_(2) produced from 4 moles of NH_(3)

A mixture of two gases A and B in the mole ratio 2:3 is kept in a 2 litre vessel. A second 3 litre vessel has the same two gases in the mole ratio 3:5 . Both gas mixtures have the same temperature and same pressure. They are allowed to intermix and the final temperature and pressure are the same as the initial values, the final volume beingh 5 litres. Given theat the molar masses are M_(A) and M_(B) . what is the mean molar mass of the final mixture :

What volume of H_(2) at NTP is required to convert 2.8 g of N_(2) into NH_(3) ?

In the reaction N_(2)+3H_(2) to 2NH_(3) , the volume ratio of the gases as 1: 3: 2 was

A mixture of 1.57 mol of N_(2), 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20 L reaction vessel at 500 K . At this temperature, the equilibrium constant K_(c ) for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium? If not, what is the direction of the net reaction?

A mixture of 1.57 mol of N_(2), 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20 L reaction vessel at 500 K . At this temperature, the equilibrium constant K_(c ) for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium? If not, what is the direction of the net reaction?

A mixture of 2 moles of NH_(3) and 3 moles of N_2 exert a pressure of 500 mm Hg pressure in a rigid container. If one mole of HCl gas is pumped into the flask what may be the resultant pressure ? (Ignore temperature change)

If 1 mole of H_(2) , 2 moles of O_(2) and 3 moles of N_(2) are mixed in a vessel and total pressure was found to be 12 atm then the partial pressure exerted by N_(2) in the vessel will be

1.5 mole of N_(2) at 77^(@)C and at a pressure of 5 atmosphere is mixed with 0.5 mole of helium at 27^(@)C and at a pressure of 2 atmosphere. The volume of the mixture is equal to the sum of their initial volume. What is the pressure of the mixture if the temperature of the mixture is 69^(@)C .