Calculate the minimum mass of NaOH required to be added in RHS to consume all the `H^(+)` present in RHS of the cell of emf + 0.701 volt at `25^(@)C` before its use. Also report the emf of the cell after addition of NaOH. `Zn|underset("0.1 M")(Zn^(2+))||underset("1 litre")(HCl)|underset("1 atm")(Pt (H_(2)g)), E_(Zn//Zn^(2+))^(@)=0.760 V`

Calculate the minimum mass of NaOH required to be added in RHS to cons

1.	Calculate the minimum mass of NaOH required to be added in RHS to consume all the `H^(+)` present in RHS of the cell of emf + 0.701 volt at `25^(@)C` before its use. Also report the emf of the cell after addition of NaOH. `Zn\|underset("0.1 M")(Zn^(2+))\|\|underset("1 litre")(HCl)\|underset("1 atm")(Pt (H_(2)g)), E_(Zn//Zn^(2+))^(@)=0.760 V`
Answer» The cell reaction is, `Zn+2H^(+) rarr Zn^(2+) +H_(2)` Applying Nernst equation, `E_(cell)=E^(@)-0.0591/2"log"([Zn^(2+)])/([H^(+)]^(2))` `0.701=0.760-0.0591/2"log" ([Zn^(2+)])/([H^(+)]^(2))` So, `"log"([Zn^(2+)])/([H^(+)]^(2))=(0.0591xx2)/0.0591=2` or `([Zn^(2+)])/([H^(+)]^(2))=10^(2)` `[H^(+)]^(2)=0.1/10^(2)=10^(-3)` `[H^(+)]=0.0316" mol L"^(-1)` Thus, 0.0316 mol/litre of NaOH is required to neutralise `H^(+)` ions. Mass of NaOH = `0.0316xx` Mol. mass of NaOH `=0.0316xx400=1.264 g` After addition of NaOH, the solution becomes neutral, i.e., the concentration of `H^(+)` ions in cathodic solution becomes `10^(-7)`. Applying again Nernst equation, `E_(cell)=E_(cell)^(@)-0.0591/2"log"([Zn^(2+)])/([H^(+)]^(2))` `=0.760-0.0591/2"log"0.1/((10^(-7))^(2))=0.3759` volt

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