`60 mL` of `H_(2)` and `42` mL of `I_(2)` are heated in a closed vessel. At equilibrium, the vessel contains `20 mL HI`. Calculate degree of dissociation of `HI`.

2 mole of H_(2) and "1 mole of "I_(2) are heated in a closed 1 litre vessel. At equilibrium, the vessel contains 0.5 mole HI. The degree of dissociation of H_(2) is

2 mole of H_(2) and "1 mole of "I_(2) are heated in a closed 1 litre vessel. At equilibrium, the vessel contains 0.5 mole HI. The degree of dissociation of H_(2) is

Two moles of H_(2) and three moles of I_(2) are taken in 2 dm^(3) vessel and heated. If the equilibrium mixture contains 0.8 moles of HI, calculate K_(p) and K_(c) for the reaction H_(2(g))+I_(2(g))hArr 2HI_((g))

Two moles of H_(2) and three moles of I_(2) are taken in 2 dm^(3) vessel and heated. If the equilibrium mixture contains 0.8 moles of HI, calculate K_(p) and K_(c) for the reaction H_(2(g))+I_(2(g))hArr 2HI_((g))

Two moles of H_(2) and three moles of I_(2) are taken in 2 dm^(3) vessel and heated. If the equilibrium mixture contains 0.8 moles of HI, calculate K_(p) and K_(c) for the reaction H_(2(g))+I_(2(g))hArr 2HI_((g))

Two moles of H_(2) and three moles of I_(2) are taken in 2 dm^(3) vessel and heated. If the equilibrium mixture contains 0.8 moles of HI, calculate K_(p) and K_(c) for the reaction H_(2(g))+I_(2(g))hArr 2HI_((g))