One mole of N(2) and 3 moles of PCl(5) a...

One mole of `N_(2)` and 3 moles of `PCl_(5)` are placed in a `100L` vessel heated to `227^(@)C`. The equilibrium pressure is 2.05 atm. Assuming ideal behaviour, calculate the degree of dissociation for `PCl_(5)` and `K_(p)` for the reaction,
`PCl_(5)(g)hArrPCl_(3)(g)+Cl_(2)(g)`

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One mole of `N_(2)` and 3 moles of `PCl_(5)` are placed in a `100L` vessel heated to `227^(@)C`. The equilibrium pressure is 2.05 atm. Assuming ideal behaviour, calculate the degree of dissociation for `PCl_(5)` and `K_(p)` for the reaction, `PCl_(5)(g)hArrPCl_(3)(g)+Cl_(2)(g)`

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One mole of `N_(2)` and 3 moles of `PCl_(5)` are placed in a `100L` vessel heated to `227^(@)C`. The equilibrium pressure is 2.05 atm. Assuming ideal behaviour, calculate the degree of dissociation for `PCl_(5)` and `K_(p)` for the reaction,
`PCl_(5)(g)hArrPCl_(3)(g)+Cl_(2)(g)`