5 moles of `SO_(2)`and 5 moles of `O_(2)` are allowed to react .At equilibrium , it was foumnd that `60%` of `SO_(2)` is used up .If the pressure of the equilibrium mixture is one aatmosphere, the parital pressure of `O_(2)` is :

11 moles of N_(2) and 12 moles of H_(2) mixture reacted in 20 litre vessel at 800 K. After equilibrium was reached, 6 mole of H_(2) was present. 3.58 litre of liquid water is injected in equibrium mixture and resultant gaseous mixture suddenly cooled to 300K. What is the final pressure of gaseous mixture? Neglect vapour pressure of liquid solution. Assume (i) all NH_(3) dissolved in water (ii) no change in volume of liquid (iii) At 300 K no reaction takes place between N_(2) and H_(2)

A nitrogen-hydrogen mixture initially in the moler ratio of 1:3 reached equilibrium to from ammonia when 25% of the N_(2)and N_(2) had reacterd .If the pressure of the system was 21 atm , the partial pressure of ammonia at the equilibrium was :

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) ?

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 :

At 1000 K , a sample of pure NO_(2) gases decomposes as : 2NO_(2)(g)hArr2NO(g)+O_(2)(g) The equilibrium constant K_(P) is 156.25 atm .Analysis showns that the partial pressure of O_(2) is 0.25 atm at equilibrium .The parital pressure o f NO_(2) at equilibrium is :

Define mole. Calculate the mass of one molecule of H_(2)O

A mixture of 3 moles of SO_(2) , 4 moles of NO_(2) , 1 mole of SO_(3) and 4 moles of NO is placed in a 2.0L vessel. SO_(2)(g)+NO_(2)(g) iff SO_(3)(g)+NO(g) . At equilibrium, the vessel is found to contain 1 mole of SO_(2) . Calculate the value of K_(C) .

N_(2)O_(3) is an unstable oxide of nitrogen and it decomposes into NO (g) and NO_(2)(g) where NO_(2)(g) is further dimerise dimerise into N_(2)O_(4) as N_(2)O_(3)(g)hArrNO_(2)(g)+NO(g)" ",K_(p_(1)=2.5 bar 2NO_(2)(g)hArrN_(2)O_(4)(g)" ": K_(P2) A flask is initially filled with pure N_(2)O_(3)(g) having pressure 2 bar and equilibria was established. At equilibrium partial pressure of NO (g) was found to be 1.5 ber. The equilibrium partial pressure of N_(2)O_(3)(g) is :

Two moles of NH_(3) when put into a previously evacuated vessel (one litre) partially dissociate into N_(2) and H_(2) . If at equilibrium one mole of NH_(3) is present, the equilibrium constant is

In the reaction C(s)+CO_(2)(g) hArr 2CO(g) , the equilibrium pressure is 12 atm. If 50% of CO_(2) reacts, calculate K_(p) .