The `E^(@)` values for the changes given below are measured againest `NHE` at `27^(@)C`. `Cu^(2+) + e rarr Cu^(+), E^(@) = + 0.15 V`, `Cu^(+) + e rarr Cu, E^(@) = + 0.50 V`, `Zn^(2+) + 2e rarr Zn, E^(@) = - 0.76 V` The temperature coefficient of emf a cell designed as `Zn"|"underset(1 M)(Zn^(2+))"||"underset(0.1 M)(Cu^(2+))"|"Cu` is `-1.4 xx 10^(-4)V` per degree. For a cell reaction in equilibrium `DeltaG = 0` and `DeltaG^(@) = -2.303 RTlog_(10)K_(c)`. The heat of reaction and entropy change during the reaction are are related by `DeltaG = DeltaH - TDeltaS`. The equilibrium constant for the disproportionation of `Cu^(+)` is:A. `8.5 xx 10^(-5)`B. `85 xx 10^(5)`C. `8.5 xx 10^(-4)`D. `8.5 xx 10^(6)`

The `E^(@)` values for the changes given below are measured againest `

1.	The `E^(@)` values for the changes given below are measured againest `NHE` at `27^(@)C`. `Cu^(2+) + e rarr Cu^(+), E^(@) = + 0.15 V`, `Cu^(+) + e rarr Cu, E^(@) = + 0.50 V`, `Zn^(2+) + 2e rarr Zn, E^(@) = - 0.76 V` The temperature coefficient of emf a cell designed as `Zn"\|"underset(1 M)(Zn^(2+))"\|\|"underset(0.1 M)(Cu^(2+))"\|"Cu` is `-1.4 xx 10^(-4)V` per degree. For a cell reaction in equilibrium `DeltaG = 0` and `DeltaG^(@) = -2.303 RTlog_(10)K_(c)`. The heat of reaction and entropy change during the reaction are are related by `DeltaG = DeltaH - TDeltaS`. The equilibrium constant for the disproportionation of `Cu^(+)` is:A. `8.5 xx 10^(-5)`B. `85 xx 10^(5)`C. `8.5 xx 10^(-4)`D. `8.5 xx 10^(6)`
Answer» Correct Answer - B `E^(@) = (0.059)/(1)logK_(c)` or `0.35 = (0.059)/(1)logK_(c)` `:. K_(c) = 8.5 xx 10^(5)`

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What are elementary reactions ?

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