calculate `E^(@)` of the following half -cell reaction at 298 K: `Ag(NH_(3))_(2)^(+)+e^(-) rarr Ag+2NH_(3)` `{:(Ag^(+)+e^(-) rarr Ag,,E_(Ag^(+)//Ag)^(@)=0.80 V),(Ag(NH_(3))_(2)^(+) hArr Ag^(+)+2NH_(3),,K=6xx10^(-8)):}`

calculate `E^(@)` of the following half -cell reaction at 298 K: `Ag(N

1.	calculate `E^(@)` of the following half -cell reaction at 298 K: `Ag(NH_(3))_(2)^(+)+e^(-) rarr Ag+2NH_(3)` `{:(Ag^(+)+e^(-) rarr Ag,,E_(Ag^(+)//Ag)^(@)=0.80 V),(Ag(NH_(3))_(2)^(+) hArr Ag^(+)+2NH_(3),,K=6xx10^(-8)):}`
Answer» Correct Answer - 0.373 volt `{:("Anode "Ag(s) rarr Ag^(+)+e^(-)," "E^(@)=0.80" volt"),("Cathode "[Ag(NH_(3))_(2)]^(+)+e^(-) rarr Ag(s)+2NH_(3)," "E^(@)=V" volt"),(ulbar(Ag(s)+[Ag(NH_(3))_(2)]^(+) hArr Ag(s)+Ag^(+)+2NH_(3))):}` `Q=([Ag^(+)][NH_(3)]^(2))/([Ag(NH_(3))_(2)]^(+))=6xx10^(-8) (n=1) E_(cell)^(@)=(V-0.80)` At equilibrium, `E=0` `:. E=E^(@)-0.0591/n log Q` `0=(V-0.80)-0.0591/1 log (6xx10^(-8))` `V=0.373` volt

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calculate `E^(@)` of the following half -cell reaction at 298 K: `Ag(NH_(3))_(2)^(+)+e^(-) rarr Ag+2NH_(3)` `{:(Ag^(+)+e^(-) rarr Ag,,E_(Ag^(+)//Ag)^(@)=0.80 V),(Ag(NH_(3))_(2)^(+) hArr Ag^(+)+2NH_(3),,K=6xx10^(-8)):}`

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