A mixture of one mole of CO(2) and "mole...

A mixture of one mole of `CO_(2)` and "mole" of `H_(2)` attains equilibrium at a temperature of `250^(@)C` and a total pressure of `0.1` atm for the change `CO_(2)(g)+H_(2)(g) hArr CO(g)+H_(2)O(g)`. Calculate `K_(p)` if the analysis of final reaction mixture shows `0.16` volume percent of CO.

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A mixture of one mole of CO_(2) and one mole of H_(2) attains equilibrium at a temperature of 250^(@)C and a total pressure of 0.1 atm for the change CO_(2(g)) +H_(2(g)) harr CO_((g))+H_(2)O_((g)) . Calculate K_(P) if the analysis of final reaction mixture shows 0.16 volume fraction of CO

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A mixture of one mole of `CO_(2)` and "mole" of `H_(2)` attains equilibrium at a temperature of `250^(@)C` and a total pressure of `0.1` atm for the change `CO_(2)(g)+H_(2)(g) hArr CO(g)+H_(2)O(g)`. Calculate `K_(p)` if the analysis of final reaction mixture shows `0.16` volume percent of CO.

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