An equilibrium mixture in a vessel of capacity `100` litre contain `1 "mol" N_(2).2"mol"O_(2) "and" 3 "mol" NO`. Number of moles of `O_(2)` to be added so that at new equilibrium the conc. Of `NO` is found to be `0.04` mol//lt.

An equilibrium mixture in a vessel of capacity 100 litre contain 1 mol N_(2) , 2 mol O_(2) and 3 mol NO. Find number of moles of O_(2) to be added, so that at new equilibrium the concentration of No is 0.04 mol/lit.

Initially 0.4 mole of N_(2) and 0.9 mole of O_(2) were mixed then moles of N_(2),O_(2) and NO at equilibrium are (approximate):

A reaction system in equilibrium according to reaction 2SO_(2)(g)+O_(2)(g)hArr2SO_(3)(g) in one litre vessel at a given temperature was found to be 0.12 mole each of SO_(2) and SO_(3) and 5 mole of O_(2) In another vessell of one litre contains 32 g of SO_(2) at the same temperature. What mass of O_(2) must be added to this vessel in order that at equilibrium 20% of SO_(2) is oxidized to SO_(3) ?

A vessel contains 0.1 mol e of He, 0.1 mole of O_(2) and 0.3 mole of N_(2) . The total pressure is 1 atomosphere. The pressure exerted by O_(2) is

An equilibrium mixture CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) present in a vessel of one litre capacity at 815^(@)C was found by analysis to contain 0.4 mol of CO, 0.3 mol of H_(2)O, 0.2 mol of CO_(2) and 0.6 mol of H_(2) . a. Calculate K_(c) b. If it is derived to increase the concentration of CO to 0.6 mol by adding CO_(2) to the vessel, how many moles must be addes into equilibrium mixture at constant temperature in order to get this change?

The number of moles of K_(2)Cr_(2)O_(7) reduced by 1 mol of Sn^(2+) ions is

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