329986 The potential of hydrogen electrode is\({\rm{ - 118 mV}}\). The \({{\rm{H}}^{\rm{ + }}}\) concentration of the solution is

329987 Emf of the cell
\(\left. {{\rm{Ni}}} \right \vert \left. {{\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}\left( {{\rm{0}}{\rm{.1M}}} \right)} \right\vert \left. {{\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}\left( {{\rm{1}}{\rm{.0M}}} \right)} \right \vert {\rm{Au}}\) will be
\({\rm{E}}_{\left. {{\rm{Ni}}} \right \vert {\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}}^{\rm{^\circ }}{\rm{ = 0}}{\rm{.25,}}\,\,{\rm{E}}_{\left. {{\rm{Au}}} \right \vert {\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}}^{\rm{^\circ }}{\rm{ = - 0}}{\rm{.15V}}\)

329988 The cell,
\(\left. {{\rm{Zn}}} \right \vert \left. {{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right\vert \left. {{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right \vert {\rm{Cu(E}}_{{\rm{cell}}}^{\rm{o}}{\rm{ = 1}}{\rm{.10V)}}\), was allowed to be completely discharged at 298 K. The relative concentration of \({\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}\,\,{\rm{to}}\,\,{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{,}}\left[ {\frac{{{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}}}{{{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}}}} \right]\) is

329989 The electrode potential becomes equal to standard electrode potential when reactants and products concentration ratio is

329990 The oxidation potential of \({\rm{0}}{\rm{.05}}\,\,{\rm{M}}\,\,{{\rm{H}}_{\rm{2}}}{\rm{S}}{{\rm{O}}_{\rm{4}}}\) is

329986 The potential of hydrogen electrode is\({\rm{ - 118 mV}}\). The \({{\rm{H}}^{\rm{ + }}}\) concentration of the solution is

329987 Emf of the cell
\(\left. {{\rm{Ni}}} \right \vert \left. {{\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}\left( {{\rm{0}}{\rm{.1M}}} \right)} \right\vert \left. {{\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}\left( {{\rm{1}}{\rm{.0M}}} \right)} \right \vert {\rm{Au}}\) will be
\({\rm{E}}_{\left. {{\rm{Ni}}} \right \vert {\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}}^{\rm{^\circ }}{\rm{ = 0}}{\rm{.25,}}\,\,{\rm{E}}_{\left. {{\rm{Au}}} \right \vert {\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}}^{\rm{^\circ }}{\rm{ = - 0}}{\rm{.15V}}\)

329988 The cell,
\(\left. {{\rm{Zn}}} \right \vert \left. {{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right\vert \left. {{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right \vert {\rm{Cu(E}}_{{\rm{cell}}}^{\rm{o}}{\rm{ = 1}}{\rm{.10V)}}\), was allowed to be completely discharged at 298 K. The relative concentration of \({\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}\,\,{\rm{to}}\,\,{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{,}}\left[ {\frac{{{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}}}{{{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}}}} \right]\) is

329989 The electrode potential becomes equal to standard electrode potential when reactants and products concentration ratio is

329990 The oxidation potential of \({\rm{0}}{\rm{.05}}\,\,{\rm{M}}\,\,{{\rm{H}}_{\rm{2}}}{\rm{S}}{{\rm{O}}_{\rm{4}}}\) is

329986 The potential of hydrogen electrode is\({\rm{ - 118 mV}}\). The \({{\rm{H}}^{\rm{ + }}}\) concentration of the solution is

329987 Emf of the cell
\(\left. {{\rm{Ni}}} \right \vert \left. {{\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}\left( {{\rm{0}}{\rm{.1M}}} \right)} \right\vert \left. {{\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}\left( {{\rm{1}}{\rm{.0M}}} \right)} \right \vert {\rm{Au}}\) will be
\({\rm{E}}_{\left. {{\rm{Ni}}} \right \vert {\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}}^{\rm{^\circ }}{\rm{ = 0}}{\rm{.25,}}\,\,{\rm{E}}_{\left. {{\rm{Au}}} \right \vert {\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}}^{\rm{^\circ }}{\rm{ = - 0}}{\rm{.15V}}\)

329988 The cell,
\(\left. {{\rm{Zn}}} \right \vert \left. {{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right\vert \left. {{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right \vert {\rm{Cu(E}}_{{\rm{cell}}}^{\rm{o}}{\rm{ = 1}}{\rm{.10V)}}\), was allowed to be completely discharged at 298 K. The relative concentration of \({\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}\,\,{\rm{to}}\,\,{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{,}}\left[ {\frac{{{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}}}{{{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}}}} \right]\) is

329989 The electrode potential becomes equal to standard electrode potential when reactants and products concentration ratio is

329990 The oxidation potential of \({\rm{0}}{\rm{.05}}\,\,{\rm{M}}\,\,{{\rm{H}}_{\rm{2}}}{\rm{S}}{{\rm{O}}_{\rm{4}}}\) is

329986 The potential of hydrogen electrode is\({\rm{ - 118 mV}}\). The \({{\rm{H}}^{\rm{ + }}}\) concentration of the solution is

329987 Emf of the cell
\(\left. {{\rm{Ni}}} \right \vert \left. {{\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}\left( {{\rm{0}}{\rm{.1M}}} \right)} \right\vert \left. {{\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}\left( {{\rm{1}}{\rm{.0M}}} \right)} \right \vert {\rm{Au}}\) will be
\({\rm{E}}_{\left. {{\rm{Ni}}} \right \vert {\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}}^{\rm{^\circ }}{\rm{ = 0}}{\rm{.25,}}\,\,{\rm{E}}_{\left. {{\rm{Au}}} \right \vert {\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}}^{\rm{^\circ }}{\rm{ = - 0}}{\rm{.15V}}\)

329988 The cell,
\(\left. {{\rm{Zn}}} \right \vert \left. {{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right\vert \left. {{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right \vert {\rm{Cu(E}}_{{\rm{cell}}}^{\rm{o}}{\rm{ = 1}}{\rm{.10V)}}\), was allowed to be completely discharged at 298 K. The relative concentration of \({\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}\,\,{\rm{to}}\,\,{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{,}}\left[ {\frac{{{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}}}{{{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}}}} \right]\) is

329989 The electrode potential becomes equal to standard electrode potential when reactants and products concentration ratio is

329990 The oxidation potential of \({\rm{0}}{\rm{.05}}\,\,{\rm{M}}\,\,{{\rm{H}}_{\rm{2}}}{\rm{S}}{{\rm{O}}_{\rm{4}}}\) is

329986 The potential of hydrogen electrode is\({\rm{ - 118 mV}}\). The \({{\rm{H}}^{\rm{ + }}}\) concentration of the solution is

329987 Emf of the cell
\(\left. {{\rm{Ni}}} \right \vert \left. {{\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}\left( {{\rm{0}}{\rm{.1M}}} \right)} \right\vert \left. {{\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}\left( {{\rm{1}}{\rm{.0M}}} \right)} \right \vert {\rm{Au}}\) will be
\({\rm{E}}_{\left. {{\rm{Ni}}} \right \vert {\rm{N}}{{\rm{i}}^{{\rm{2 + }}}}}^{\rm{^\circ }}{\rm{ = 0}}{\rm{.25,}}\,\,{\rm{E}}_{\left. {{\rm{Au}}} \right \vert {\rm{A}}{{\rm{u}}^{{\rm{3 + }}}}}^{\rm{^\circ }}{\rm{ = - 0}}{\rm{.15V}}\)

329988 The cell,
\(\left. {{\rm{Zn}}} \right \vert \left. {{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right\vert \left. {{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{(1M)}}} \right \vert {\rm{Cu(E}}_{{\rm{cell}}}^{\rm{o}}{\rm{ = 1}}{\rm{.10V)}}\), was allowed to be completely discharged at 298 K. The relative concentration of \({\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}\,\,{\rm{to}}\,\,{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}{\rm{,}}\left[ {\frac{{{\rm{Z}}{{\rm{n}}^{{\rm{2 + }}}}}}{{{\rm{C}}{{\rm{u}}^{{\rm{2 + }}}}}}} \right]\) is

329989 The electrode potential becomes equal to standard electrode potential when reactants and products concentration ratio is

329990 The oxidation potential of \({\rm{0}}{\rm{.05}}\,\,{\rm{M}}\,\,{{\rm{H}}_{\rm{2}}}{\rm{S}}{{\rm{O}}_{\rm{4}}}\) is