Electrochemistry Notes - UNIT 1 2023-24 PDF

Summary

These notes cover UNIT 1 of Electrochemistry, discussing topics such as electrodes, electrochemical cells, and batteries. The content explains concepts like conductor types and electrode potential, and provides a foundational understanding of the subject matter.

Full Transcript

Unit – I

ELECTROCHEMISTRY
 Unit Syllabus

⮚Electrodes- Electrode potential, standard electrode potential.

⮚Types of electrodes – calomel, quinhydrone and glass electrode.

⮚Single electrode potential and its determination.

⮚Electrochemical cells.

⮚Nernst equation - determination of pH of a solution by using
quinhydrone and glass electrode.

⮚Electrochemical series and its applications.

⮚Batteries – Primary (dry battery) and secondary batteries (Lead –
acid storage battery and Lithium ion battery) and next generation
batteries
 Introduction
⮚ Electrochemistry is a branch of chemistry.
⮚ It deals with the chemical reactions produced by passing
electric current through an electrolyte or production of
electric current through a chemical reaction

Conductors

Conductor is a material which allows free flow of electricity.

Example: All metals, graphite, fused salts, solution of electrolytes

Non-conductors (Insulators)

Insulators are materials which donot conduct electrical current

Example: Wood, plastics, most of non metals.
 Types of conductors

(i) Metallic conductors :
The solid material, which conduct electric current due to the
movement of electron from one end to the other end without
producing chemical reaction.

Examples : All metals & graphite.

(ii) Electrolytic conductors :

They conduct electric current due to the movement of ions from
one electrode to another electrode in solution or in fused state.
This process is accompanied by a chemical reaction.

Examples : Metal ions dissolved solvent
Origin of electrode potential

When a metal (M) is placed in a solution of its own salt (Mn+) one of
the two processes are possible
(i) Metal atoms go into solution in the form of
ions.
Example : M → Mn+ + ne- (Oxidation)

(ii) Metal ions from solution may deposit on the
metal
Mn+ + ne- → M (reduction)

e- e-
Electrode Potential
Zn Cu

Zn2+ Cu2+
Zn → Zn2+ + 2e- Cu2+ + 2e-→ Cu
 Electrode Potential
At equilibrium, the potential difference becomes a constant value
which is known as the electrode potential of the metal.
Thus the tendency of the electrode to lose electrons is called
Oxidation potential and tendency of an electrode to gain electrons is
called reduction potential.

Single electrode potential (E) :
It is the tendency of a metallic electrode to lose or gain electrons when
it is in contact with a solution of its own salt.

Standard electrode potential (Eo) :
It is the tendency of a metallic electrode to lose or gain electrons when
it is in contact with a solution of its own salt of 1M concentration at
25oC.
 Types of Electrodes
Reference Electrode:
A reference electrode is that electrode whose potential is known and
remain constant.
e.g. Saturated calomel electrode (ESCE = 0.242 V)

Indicator Electrode:
An indicator electrode is that electrode whose potential depends on
the activity of ions being titrated or estimated.
e.g. To carry out acid-base potentiometric titration Hydrogen gas.
Quinhydrone electrode and glass electrodes are used as indicator
electrode.
 Measurement of Single Electrode Potential And Its
Applications.
Measurement of single electrode potential

It is impossible to evaluate the absolute value of a single electrode
potential.

Reference (or) Standard electrode
The potential of unknown electrode can be measured by coupling it
with another electrode, called reference electrode whose electrode
potential is already known.
Examples : Standard hydrogen electrode, Standard calomel
electrodes.
Standard hydrogen electrode (SHE)
It is also called as Primary reference electrode because. The potential
developed by this electrode is arbitrarily fixed as zero
 Construction

⮚ It consists of a platinum foil that is connected to a platinum wire
sealed in a glass tube.

⮚The Pt foil is dipped in 1M HCl. H2 gas of 1 atm pressure is passed
through the side of glass tube.

H 2 (g) → 2H+ + 2e-

The standard electrode potential of SHE is arbitrarily fix as zero

Pt , H2 (1atm) / H+(1M) ; E0 = 0 V
 Limitations (or) drawbacks of SHE
⮚ It is difficult to get pure hydrogen gas.

⮚ The pressure of hydrogen is to be
kept 1 atm all the time.

⮚ It is difficult to set up and transport.

⮚ Hydrogen gas reduces many ions like
Ag+ and affects compounds of Hg, Ag
etc

⮚ A large volume of test solution is
required.

⮚ It cannot be used in solutions of redox
systems, the solution may poison
platinum surface.
 Saturated calomel electrode (SCE)
(Secondary reference electrode)

⮚ Glass tube containing pure Hg at the bottom over which
mercurous chloride is placed. The remaining portion of the tube is
filled with saturated solution of KCl.

⮚ The bottom of the tube is sealed with a platinum wire. The side
tube is used for making electrical contact with a salt bridge.

Hg | Hg2 Cl2(s) | KCl (Saturated, Solution) Eº = 0.2422V

2Hg(l) + 2Cl- → Hg2Cl2(s) + 2e-
HgCl2 + 2e- → 2 Hg+ + Cl-
KCl (v)

0.1N 0.3335 V

1N 0.281 V

Saturated 0.2422 V
Measurement of single electrode potential using a reference
electrode (saturated calomel electrode)

Hg 2 Cl 2 (s) → 2Hg+ (s ) + 2Cl-
The emf of the cell is measured using a potentiometer.
The value of Ecell = 1.0025 volt.

Ecell = E oright----- Eoleft
Ecell = E calo --- EoZn
E oZn = E ocal ---- Eocell
= + 0.2422 – 1.0025 = – 0.7603 V
 Cell Terminology

1. Current: Flow of electrons through a conductor.

2. Electrode: Electrode is a material (rod, bar, strip) which conducts
electrons.

3. Anode: Electrode at which oxidation occurs.

4. Cathode: Electrode at which reduction occurs.

5. Electrolyte: Water soluble substance forming ions in solution
and conducts electric current
6. Anode compartment: Compartment of the cell in which the
oxidation half reaction occurs. It contains the anode

7. Cathode compartment: Compartment of the cell in which the
reduction half reaction occurs. It contains the cathode

8. Half–cell: It is the part of a cell, which contains an electrode
dipped in an electrolyte. If oxidation occurs in this half-cell, then it
is called the oxidation half cell. If reduction occurs at the cell, it is
called the reduction half-cell.

9. Cell: Device consisting of two half cell. The two half cells are
connected through one wire.

10. Salt bridge: Contains solutions of a salt (KCl, KNO3 or NH4NO3)
that literally serve as a bridge to completed the circuit, maintain
electro neutrality of electrolyte and minimize. For precise
measurement of potential a salt bridge is used.
 Types of cells
A cell is a device consisting of two half cells. Each half cell consists of
an electrode dipped in an electrolyte solution. The two half cells are
connected through one wire.
S.No Electrolytic cell Electrochemical cell

1 Electrical energy converted to Chemical energy converted to
chemical energy. electrical energy.
Example: Electrolysis, Example: Daniel Cell
electroplating.
2 Anode carries +ve charge. Anode carries –ve charge
3 Cathode carries – ve charge. Cathode carries +ve charge.

4 Electrons are supplied to the cell Electrons are drawn from the cell
from an external source.
5 Amount of electricity is measured Emf produced is measured by
by coulometer potentiometer
6 Extent of chemical change is Emf of the cell depends on the
governed by Faraday’s laws. concentration of the electrolyte and the
nature of the electrode.
Electrolytic cell - Example : Electrolysis of HCl.

At anode : 2Cl– → Cl2 + 2e- (oxidation)

At cathode : 2H+ + 2e– → H2 (reduction)
Electrochemical cell - Example : Daniel cell

(at anode) (at cathode)

Cu2+ + Zn → Zn2+ + Cu
(net cell reaction)
 Components of a Cell
At anode : Oxidation of Zn to Zn2+ place with the liberation of
electrons.

At cathode : Reduction of Cu2+ to Cu place by the acceptance of
electrons. The electrons liberated in oxidation reaction flow
through external wire and are consumed by the copper ions at the
cathode.

Salt bridge : It consists of a U-tube containing a saturated
solution of KCl or (NH4)2NO3 agar–agar gel. It connects the two
half cells.

Functions
⮚ It eliminates liquid junction potential.
⮚ It provides a path for the flow of electrons between two
half cells.
 Representation (Cell diagram)
1. Galvanic cell consists of two electrodes, anode and
cathode

1. Anode is written on the LHS and cathode on RHS

1. The anode is written with the metal first and then the
electrolyte which are separated by a vertical line
Examples : Zn/Zn2+ (or) Zn/ZnSO4

1. The cathode is written with the electrolyte first and then
the metal.

Examples : Cu2+/Cu (or) CuSO4/Cu
5. The two half cells are separated by a salt bridge, which is
indicated by two vertical lines.
Cell is represented as Zn/ZnSO4 (1M) // ) CuSO4 (1M) /Cu
Nernst equation for electrode potential
Ref: Sri Krishna Hitech Publishing Company Pvt. Ltd.
 Quinhydrone electrode
⮚ The quinhydrone electrode is a type of redox electrode which can be
used to measure the hydrogen ion concentration (pH) of a solution.
⮚ The electrode consists of an inert metal electrode (usually a
platinum wire) in contact with quinhydrone crystals and a water-
based solution.
⮚ Quinhydrone is slightly soluble in water, dissolving to form a mixture
of two substances, quinone and hydroquinone
⮚ Each one of the two substances can easily be oxidised or reduced
to the other. The potential at the inert electrode depends on the ratio
of the activity of two substances.
⮚ Quinone + 2H+ +2e− ⇆ Hydroquinone
From the Nernst equation: E= Eo + 2.303RT log [Q][H+]2 (or)
2F [QH2]
E= Eo - 2.303RT log [QH2]
2F [Q] [H+]2

If quinone and hydroquinone are taken in equimolar concentrations, then
[Q] = [QH2] then the above reaction reduces to

E= Eo - 2.303RT log 1 = Eo - 2.303RT log 1
2F [H+]2 F [ H +]

EQ = E0 - 0.0592v pH = 0.6994v - 0.0592v pH

Construction and working
QH electrode can very easily be set up by adding a pinch of
quinhydrone powder to the experimental solution with stirring until the
solution is saturated. Then indicator electrode usually a bright platinum
is inserted in it. For determining the pH value, this half cell is combined
with saturated calomel electrode and the emf of the cell is determine
potentiometrically.
Quinhydrone electrode in a cell.
The complete cell may be represented as
Hg2Cl2(s) | Hg+, KCl(sat), // H+(unknown, Pt | H2Q, Q,

Ecell = EQH – Ecal

Ecell = 0.6994v - 0.0592 pH - 0.2422v

pH = 0.6994v – 0.2422v - Ecell
0.0592
 Merits and Demerits of the electrode:
Merits:
i.Electrode is easy to set up.
ii.It is also easy to handle.
iii.It can be functioning satisfactorily also in highly acidic solution.
iv.It is used to measure the pH of aqueous and non-aqueous
solution.
Demerits:
i.This electrode is functioning only in the pH range of 1 to 8
ii.With the solution of pH greater than 8, the activity ratio is no longer
remain equal to 1.
 Glass electrode
⮚When two solutions of different pH values are separated by a thin
glass membrane, there develops a difference of potential between
the surfaces of the membrane.

⮚The potential value developed is proportional to the difference
in pH of the test solution.

⮚The glass membrane functions as an ion exchange resin and
an equilibrium is set up between the Na+ ions of the glass and H+
ions in the solution.

⮚For a particular type of glass the potential difference varies with H+
ion concentration, and is given by the expression
EG = EoG + 0.0591 log [H+]
EG = EoG - 0.0591 pH
 Glass electrode.
Construction
The glass electrode assembly consists of a thin glass bulb filled
with 0.1 N HCl and a silver wire coated with silver chloride
immersed in it.
The Ag/AgCl electrode here acts as the internal reference electrode.
The glass electrode is represented as
Ag | AgCl(s) | 0.1 M HCl | glass. Or Pt.0.1MHCl|Glass+

To carry out the determination of pH of a solution, the glass
electrode is connected with a saturated calomel electrode. The
emf of the cell is measured.
 Glass electrode.
The cell is therefore represented as;
Ag, AgCl / HCl (0.1 N) / Glass // SCE
Ecell = Eright – Eleft = Ecal - EG

pH = EoG -0.2422v – Ecell
0.0592v
The E0G value of a glass electrode can be determined by using a
solution of known pH
Advantages of Glass electrode
i) To determine pH of any solution
ii) Small quantity of solution is sufficient for determination
iii) Used even in the presence of metallic ions and poisons
iv) Equilibrium is easily reached
 Merits and Demerits of the electrode:
Merits:
i.It provides a measure of pH in the pH range of 1 – 9.
ii.Using a pH meter, pH of the solution can be directly read.
iii.The electrode can be used in all aqueous solutions.
iv.Electrode is not affected by oxidizing and reducing agents or by any
organic compound.
v.pH can be determined even for small volume of solution.

Demerits:
i.The electrode cannot function in highly acidic or alkaline medium
ii.It cannot produce proper response with pH > 9 or