An aqueous solution of `NaCl` on electrolysis gives `H_(2)(g), Cl_(2)(g),` and `NaOH` accroding to the reaction `:` `2Cl^(c-)(aq)+2H_(2)Orarr2overset(c-)(O)H(aq)+H_(2)(g)+Cl_(2)(g)` A direct current of `25A` with a current efficiency of `62%` is passed through `20L` of `NaCl` solution `(20%` by weight`)`. Write down the reactions taking place at the anode and cathode. How long will it take to produce `1 kg ` of `Cl_(2)`? What will be the molarity of the solution with respect to hydroxide ion ? `(` Assume no loss due to evaporation . `)`

An aqueous solution of `NaCl` on electrolysis gives `H_(2)(g), Cl_(2)(

1.	An aqueous solution of `NaCl` on electrolysis gives `H_(2)(g), Cl_(2)(g),` and `NaOH` accroding to the reaction `:` `2Cl^(c-)(aq)+2H_(2)Orarr2overset(c-)(O)H(aq)+H_(2)(g)+Cl_(2)(g)` A direct current of `25A` with a current efficiency of `62%` is passed through `20L` of `NaCl` solution `(20%` by weight`)`. Write down the reactions taking place at the anode and cathode. How long will it take to produce `1 kg ` of `Cl_(2)`? What will be the molarity of the solution with respect to hydroxide ion ? `(` Assume no loss due to evaporation . `)`
Answer» `a.` At cathode`: 2Cl^(c-) rarr Cl_(2)+2e^(-)` At anode `: 2H_(2)O+2e^(-) rarr 2 overset(c-)(O)H +H_(2)` `b. [2e^(-)+2F=2xx96500C-=1 mol `of `Cl_(2)=71g]` or `1F=96500C=1Eq` or `Cl_(2)=35.5g` Since current efficiency is `50%` `:.` Current `=96.5xx(50)/(100)=(96.5)/(2)` Use direct relation, `W_(Cl_(2))=(Ew_((Cl_(2)))xxIxxt)/(96500C)` `35.5g=(35.5gxx96.5//2xxt)/(96500C)` `:.t=(96500xx35.5xx2)/(35.5xx96.5)=2000s` `2000s=(2000)/(3600)=0.55h` `c.` `Eq` of `overset(c-)(O)H` formed`=Eq` of `Cl_(2)` `=(35.5g)/(35.5g)=1Eq` `[overset(c-)(O)H]=(Equival ent)/(V_(1))=(1)/(100L)=10^(-2)N` `d.` `pOH=-log [10^(-2)]=2impliespH=14-2=12`

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