Equilivalent amounts of `H_(2)` and `I_(2)` are heated in a closed vessel till equilibrium is obtained. If `80%` of the hydrogen is converted to `HI`, the `K_(c)` at this temperature is

Equivalent amounts of H_(2) and I_(2) are heated in a closed vessel till equilibrium is obtained. If 80% of the hydrogen is converted to HI , the K_(c) at this temperature is

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

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 .

4g H_(2) & 127g I_(2) are mixed "&" heated in "10" lit closed vessels until equilibrium is reached. If the equilibrium concentration of HI is 0.05M total number of moles present at equilibrium is

4 g H_(2) & 127 g I_(2) are mixed & heated in 10 lit closed vessel until equilibrium is reached. If the equilibrium concentration of HI is 0.05 M, total number of moles present at cquilibrium is

4 g H_(2) & 127 g I_(2) are mixed & heated in 10 lit closed vessel until equilibrium is reached. If the equilibrium concentration of HI is 0.05 M, total number of moles present at cquilibrium is