Thermal decomposition of gaseous X(2) to...

Thermal decomposition of gaseous `X_(2)` to gaseous `X` at `298K` takes place according to the following equation:
`X(g)hArr2X(g)`
The standard reaction Gibbs energy `Delta_(r)G^(@)`, of this reaction is positive. At the start of the reaction, there is one mole of `X_(2)` and no `X`. As the reaction proceeds, the number of moles of `X` formed is given by `beta`. Thus `beta_("equilibrium")` is the number of moles of `X` formed at equilibrium. The reaction is carried out at a constant total pressure of 2 bar. Consider the gases to behave ideally.
[Given, `R=0.083L` bar `K^(-1) mol^(-1)`)
The equilibrium constant `K_(p)` for this reaction at `298K`, in terms of `beta_("equilibrium")` is

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Thermal decomposition of gaseous X_(2) to gaseous X at 298K takes place according to the following equation: X(g)hArr2X(g) The standard reaction Gibbs energy Delta_(r)G^(@) , of this reaction is positive. At the start of the reaction, there is one mole of X_(2) and no X . As the reaction proceeds, the number of moles of X formed is given by beta . Thus beta_("equilibrium") is the number of moles of X formed at equilibrium. The reaction is carried out at a constant total pressure of 2 bar. Consider the gases to behave ideally. [Given, R=0.083L bar K^(-1) mol^(-1) ) The incorrect statement among the following for this reaction, is

The equilibrium constant for the reaction w+x hArr y+z is 9 . If one mole of each of w and x are mixed and there is no change in volume, the number of moles of y for formed is

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