Explain the different conditions when an external potential is applied in the opposite direction in a galvanic cell (Voltaic cell) by taking a suitable cell example.
(N/A) Condition-$I$: (Condition in which the flow of current continues through the galvanic cell or $E_{\text{ext}} < 1.1 \ V$): According to diagram-$(a)$,if an external opposite potential is applied to the galvanic cell and increased slowly,we find that the reaction continues to take place until the opposing voltage reaches the value $1.1 \ V$. The redox reaction continues in the forward direction and the reaction does not stop.
$(b)$ Condition-$II$: (Condition in which the galvanic cell is stopped or $E_{\text{ext}} = 1.1 \ V$): According to diagram-$(b)$,when the external potential reaches $1.1 \ V$,the reaction stops altogether and no current flows through the cell. Any further increase in the external potential starts the reaction in the opposite direction (electrolytic cell).
$(c)$ Condition-$III$: (Condition in which the cell acts as an electrolytic cell or $E_{\text{ext}} > 1.1 \ V$): If the external potential is increased beyond $1.1 \ V$,the reaction proceeds in the reverse direction,and the cell acts as an electrolytic cell. Electrons flow from the copper electrode to the zinc electrode,and current flows from the zinc electrode to the copper electrode.
$(b)$ Condition-$II$: (Condition in which the galvanic cell is stopped or $E_{\text{ext}} = 1.1 \ V$): According to diagram-$(b)$,when the external potential reaches $1.1 \ V$,the reaction stops altogether and no current flows through the cell. Any further increase in the external potential starts the reaction in the opposite direction (electrolytic cell).
$(c)$ Condition-$III$: (Condition in which the cell acts as an electrolytic cell or $E_{\text{ext}} > 1.1 \ V$): If the external potential is increased beyond $1.1 \ V$,the reaction proceeds in the reverse direction,and the cell acts as an electrolytic cell. Electrons flow from the copper electrode to the zinc electrode,and current flows from the zinc electrode to the copper electrode.
Explore More
Similar Questions
Which of the following is $NOT$ a function of a salt bridge?
What is the molar conductivity of $CH_3-CO_2H$ at infinite dilution?
Given that,
$\wedge_{m}^{o}(CH_3-CO_2)_2Ba = x_1 \ S \ cm^2 \ mol^{-1}$
$\wedge_{m}^{o}(BaCl_2) = x_2 \ S \ cm^2 \ mol^{-1}$
$\wedge_{m}^{o}(HCl) = x_3 \ S \ cm^2 \ mol^{-1}$
Given that,
$\wedge_{m}^{o}(CH_3-CO_2)_2Ba = x_1 \ S \ cm^2 \ mol^{-1}$
$\wedge_{m}^{o}(BaCl_2) = x_2 \ S \ cm^2 \ mol^{-1}$
$\wedge_{m}^{o}(HCl) = x_3 \ S \ cm^2 \ mol^{-1}$
Assertion : Galvanised iron does not rust.
Reason : Zinc has a more negative electrode potential than iron.
Reason : Zinc has a more negative electrode potential than iron.
MediumAIIMS 2017
View Solution$A$ hypothetical electrochemical cell is shown below $A | A^{+} (xM) || B^{+} (yM) | B$. If the cell potential is $+0.20 \ V$,the cell reaction is :-
Medium
View SolutionIn a dry cell,which element acts as the negative electrode?
Vedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo