At `227^(@)C` the reaction `2SO_(2(g))+O_(2(g))hArr2SO_(3(g))` is
carried out in a `10` litre vessel till equilibrium is reached. At
equilibrium moles of `SO_(2)` equal to moles of `SO_(3)`. Find
moles of `O_(2)` at equilibrium (Given `:` `K_(C)=10^(2)` mole `lit^(-1)`)

The reaction, 2SO_(2(g)) + O_(2(g))hArr2SO_(3(g)) is carried out in a 1 dm^(3) and 2 dm^(3) vessel separately. The ratio of the reaction velocity will be

The reaction, 2SO_(2(g)) + O_(2(g))hArr2SO_(3(g)) is carried out in a 1 dm^(3) and 2 dm^(3) vessel separately. The ratio of the reaction velocity will be

Kp value for 2SO_(2(g)) + O_(2(g)) hArr 2SO_(3(g)) is 5.0 atm^(-1) . What is the cquilibrium partial pressure of O_(2) if the equilibrium pressures of SO_(2) and SO_(3) are equal ?

The equilibrium constant for the reaction 2SO_(2(g)) + O_(2(g)) rarr 2SO_(3(g)) is 5. If the equilibrium mixture contains equal moles of SO_(3) and SO_(2) , the equilibrium partial pressure of O_(2) gas is

The value of K_p for the reaction, 2SO_2(g)+O_2(g) hArr 2SO_3(g) is 5 what will be the partial pressure of O_2 at equilibrium when equal moles of SO_2 and SO_3 are present at equilibrium ?

A mixture of 2 moles of N_(2) and 8 moles of H_(2) are heated in a 2 lit vessel, till equilibrium is established. At equilibrium, 04 moles of N_(2) was present. The equilibrium concentration of H_(2) will be

For the reaction, 2SO_(2(g))+O_(2(g))hArr2SO_(3(g)) What is K_(c) when the equilibrium concentration of [SO_(2)]=0.60M,[O_(2)]=0.82Mand[SO_(3)]=1.90M ?

For the reaction 2SO_(3)(g)hArr2SO_(2(g))+O_(2(g)) (K_(C))/(K_(p)) will be :-

For a reaction, 2SO_(2(g))+O_(2(g))hArr2SO_(3(g)) , 1.5 moles of SO_(2) and 1 mole of O_(2) are taken in a 2 L vessel. At equilibrium the concentration of SO_(3) was found to be 0.35 mol L^(-1) The K_(c) for the reaction would be

The equilibrium constant for the reaction, 2SO_(2)(g)+O_(2)(g)hArr 2SO_(3)(g) at 1000 K is "3.5 atm"^(-1) . What would be the partial pressure of oxygen gas, if the equilibrium is found to have equal moles of SO_(2) and SO_(3) ? (Assume initial moles of SO_(2) equal to that of initial moles of O_(2) )