A silver electrode is immersed in saturated `Ag_(2)SO_(4(aq))`. The potential difference between the silver and the standard hydrogen electrode is found to be `0.711V` Determine `K_(SP)(AgSO_(4))`. Given `E_(Ag^(+)//Ag)^(@)=0799V`.

A silver electrode is immersed in saturated `Ag_(2)SO_(4(aq))`. The po

1.	A silver electrode is immersed in saturated `Ag_(2)SO_(4(aq))`. The potential difference between the silver and the standard hydrogen electrode is found to be `0.711V` Determine `K_(SP)(AgSO_(4))`. Given `E_(Ag^(+)//Ag)^(@)=0799V`.
Answer» The given cell is `PtH_(2)\|(H^(+)),(1M)\|\|(Ag_(2)SO_(4(aq.))),("saturated")\|Ag` The reaction are, `H_(2) rarr 2H^(+) + 2e` `2Ag^(+) + 2e rarr 2Ag` Thus, `E_(cell) = E_(OP_(H)) + E_(RP_(H))` `= 0.711 = 0.799 + (0.059)/(2)log[Ag^(+)]^(2)` `:. log[(1)/([Ag^(+)]^(2))] = ([0.799 - 0.711] xx 2)/(0.059) = 3` `:. [Ag^(+)]^(2) = 10^(-3)` `:. [Ag^(+)]^(2) = 3.2 xx 10^(-2)` Now the solubility equilibrium is, `Ag_(2)SO_(4) hArr 2Ag^(+) + SO_(4)^(2-)` `K_(SP) = (Ag^(+))^(2)(SO_(4)^(2-))` `= (3.2 xx 10^(-2))^(2)((3.2 xx 10^(-2))/(2))` `= 1.6 xx 10^(-5)` (Note that if `[Ag^(+)] = 3.2 xx 10^(-2)` then `[SO_(4)^(2-)] = (1)/(2) xx 3.2 xx 10^(-2))`

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A silver electrode is immersed in saturated `Ag_(2)SO_(4(aq))`. The potential difference between the silver and the standard hydrogen electrode is found to be `0.711V` Determine `K_(SP)(AgSO_(4))`. Given `E_(Ag^(+)//Ag)^(@)=0799V`.

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