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Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEET PDF Download

Key Concepts


Electrochemical Cells 

An electrochemical cell consists of two electrodes (metallic conductors) in contact with an electrolyte (an ionic conductor).

An electrode and its electrolyte comprise an Electrode Compartment. 

Electrochemical Cells can be classified as:

(i) Electrolytic Cells: Cells in which a non-spontaneous reaction is driven by an external source of current.

(ii) Galvanic Cells: Cells which produce electricity as a result of a spontaneous cell reaction .

Note: In a galvanic cell, cathode is positive with respect to anode.

In a electrolytic cell, anode is made positive with respect to cathode.


Galvanic Cell

This cell converts chemical energy into electrical energy.

Galvanic CellGalvanic Cell

A galvanic cell is made up of two half cells i.e., anodic and cathodic. The cell reaction is of redox kind. Oxidation takes place at anode and reduction at cathode. It is also known as voltaic cell. It may be represented as shown in Fig. Zinc rod immersed in ZnSO4 behaves as anode and copper rod immersed in CuSO4 behaves as cathode.

Oxidation takes place at anode. 

Zn → Zn2  + 2e- (loss of electron : oxidation)

Reduction takes place at cathode: 

Cu2  + 2e- → Cu(gain of electron ; reduction)

Overall process: Zn(s) + Cu2+  → Cu(s) + Zn2+

In galvanic cell like Daniell cell: electrons flow from anode (zinc rod) to the cathode (copper rod) through external circuit; zinc dissolves as Zn2+  ; Cu2+  ion in the cathode cell picks up two electron and become deposited at cathode.

Representation of a cell (IUPAC Conventions): 

Let us illustrate the convention taking the example of Daniel cell.

(i) Anodic half cell is written on left and cathodic half cell on right hand side.

Zn(s) |ZnSO4(sol)||CuSO4(sol)|Cu(s)

(ii) Two half cells are separated by double vertical lines: Double vertical lines indicate slat bridge or any type of porous partition.

(iii) EMF (electromotive force) may be written on the right hand side of the cell.

(iv) Single vertical lines indicate the phase separation between electrode and electrolyte solution.

Zn|Zn2+ ||Cu2+ |Cu

(v) Invert eletrodes are represented in the bracket

Zn|ZnSO4||H |H2,Pt


Electrochemical cell and Gibbs Energy of the Reaction

Electrical work done in one second is equal to electrical potential multiplied by total charge passed. If we want to obtain maximum work from a galvanic cell then charge has to be passed reversibly. The reversible work done by a galvanic cell is equal to decrease in its Gibbs energy and therefore if the emf of the cell is E and nF is the amount of charge passed and ΔrG is the Gibbs energy of the reaction, then

Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEETIt may be remembered that E(cell) is an intensive parameter but ΔrG is an extensive thermodynamic property and the value depends on n. Thus, if we write the reaction
Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEETBut when we write the reaction

Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEET

Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEET
If the concentration of all the reacting species is unity, then E(cell)
Thus, from the measurement of ECell we can obtain an important thermodynamic quantity, ΔrG, standard Gibbs energy of the reaction.From the latter we can calculate equilibrium constant by the equation:Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEET


Relationship between ΔG and electrode potential: 

Let n, Faraday charge is taken out from a cell of e.m.f. (E) then electrical work done by the cell may be calculated as,

Work done = Charge × Potential = nFE

From thermodynamics we know that decrease in Gibbs free energy of a system is a measure of reversible or maximum obtainable work by the system if there is no work due to volume expansion

ΔG = - nFE

Under standard state ΔGº = - nFEº ............(1)

(i) From thermodynamics we know, DG = negative for spontaneous process. Thus from eq. (i) it is clear that the EMF should be ve for a cell process to be feasible or spontaneous.

(ii) When ΔG = positive, E = negative and the cell process will be non spontaneous.

Reactions             

ΔG

Spontaneous          

(-)

(+)

Non-spontaneous  

(+)

(-)

Equilibrium            

0

0

Standard free energy h, range of a cell may be calculated by electrode potential data.

Substituting the value of Eº (i.e., standard reduction potential of cathode-standard reduction potential of anode) in eq. (i) we may get ΔGº.


Measurement of Electrode Potential

Concept of electromotive force (EMF) of A Cell

Electron flows from anode to cathode in external circuit due to a pushing effect called or electromotive force (e.m.f.). EMF is called as cell potential. Unit of e.m.f. of cell is volt.

EMF of cell may be calculated as:

Ecell = reduction potential of cathode - Reduction potential of anode

Similarly, standard e.m.f. of the cell (Eº) may be calculated as

cell = Standard reduction potential of cathode - Standard reduction potential of anode.

Sign Convention of EMF

EMF of cell should be positive other wise it will not be feasible in the given direction.

Zn|ZnSO4||CuSO4|Cu   , E = 1.10 volt (Feasible)

Cu|CuSO4||ZnSO4|Zn,   E = - 1.10 volt (Not Feasible)

Salt Bridge 

Two electrolyte solutions in galvanic cells are separated using salt bridge as represented in the Fig. Salt bridge is a device to minimize or eliminate the liquid junction potential. Saturated solution of salt like KCl, KNO3, NH4Cl and NH4NO3 etc. in agar-agar gel is used in salt bridge. 

Fig: Salt bridgeFig: Salt bridgeSalt bridge contains high concentration of ions viz. K+  and NO3at the junction with electrolyte solution. Thus, salt bridge carries whole of the current across the boundary; more over the K+  and NO3- ions have same speed. Hence, salt bridge with uniform and same mobility of cations and anions completes the electrical circuit & permits the ions to migrate.

The document Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential | Chemistry Class 12 - NEET is a part of the NEET Course Chemistry Class 12.
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FAQs on Electrochemical Cells, Galvanic Cells & Measurement of Electrode Potential - Chemistry Class 12 - NEET

1. What is an electrochemical cell and how does it work?
Ans. An electrochemical cell is a device that converts chemical energy into electrical energy. It consists of two electrodes, an anode and a cathode, immersed in an electrolyte solution. The anode undergoes oxidation (loses electrons), while the cathode undergoes reduction (gains electrons). This electron transfer generates an electric current that can be used to power external devices.
2. What is a galvanic cell and how is it different from an electrolytic cell?
Ans. A galvanic cell is a type of electrochemical cell that uses spontaneous redox reactions to generate electricity. It is also known as a voltaic cell. The redox reactions occur naturally, releasing energy that is converted into electrical energy. In contrast, an electrolytic cell requires an external source of electrical energy to drive a non-spontaneous redox reaction. It is used for processes like electroplating or electrolysis.
3. How is the Gibbs energy of a reaction related to an electrochemical cell?
Ans. The Gibbs energy of a reaction, represented by ΔG, is a measure of the spontaneity of the reaction. In an electrochemical cell, the Gibbs energy change of the reaction is related to the cell potential (Ecell) through the equation ΔG = -nFEcell, where n is the number of electrons transferred and F is the Faraday constant. The negative sign indicates that a spontaneous reaction has a negative ΔG and a positive cell potential.
4. How is the electrode potential of a cell measured?
Ans. The electrode potential of a cell can be measured using a voltmeter. A standard hydrogen electrode (SHE) is used as the reference electrode with a defined potential of 0 volts. The potential difference between the reference electrode and the electrode of interest is measured using the voltmeter. This gives the electrode potential, also known as the redox potential or reduction potential, which indicates the tendency of the electrode to undergo reduction or oxidation.
5. What are some practical applications of electrochemical cells?
Ans. Electrochemical cells have a wide range of practical applications. They are commonly used in batteries to power portable electronic devices. They are also used in fuel cells to generate electricity from chemical reactions, such as the oxidation of hydrogen. Electroplating is another application where electrochemical cells are used to deposit a layer of metal onto a substrate. Additionally, electrochemical cells play a crucial role in processes like corrosion protection and wastewater treatment.
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