Electrochemistry Lecture -19 PDF

Summary

This document presents a lecture on electrochemistry, covering topics such as redox reactions, galvanic cells, standard reduction potentials, batteries, corrosion, electrolysis, and electrometallurgy. It includes detailed explanations and diagrams of each concept.

Full Transcript

Chapter 19

Lecture presentation
class 1

Electrochemistry

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 Redox Reactions
Galvanic Cells
Standard Reduction Potentials
Batteries
Corrosion
Electrolysis
Electrometallurgy

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 Oxidation–Reduction (Redox)
Reactions in which electrons are transferred from one atom
to another are called oxidation–reduction reactions.
– Redox reactions for short

Atoms that lose electrons are being oxidized; atoms that
gain electrons are being reduced.

2 Na(s) + Cl2(g) → 2 Na+Cl–(s)
Na → Na+ + 1 e– oxidation
Cl2 + 2 e– → 2 Cl– reduction

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 Oxidation and Reduction

Oxidation is the process that occurs when
– the oxidation number of an element increases;
– an element loses electrons;
– a compound adds oxygen;
– a compound loses hydrogen; or
– a half-reaction has electrons as products.

Reduction is the process that occurs when
– the oxidation number of an element decreases;
– an element gains electrons;
– a compound loses oxygen;
– a compound gains hydrogen; or
– a half-reaction has electrons as reactants.

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 Electrochemistry
Electrochemistry is the study of redox reactions that
produce or require an electric current.

The conversion between chemical energy and electrical
energy is carried out in an electrochemical cell.

Spontaneous redox reactions take place in a voltaic cell.
– Also known as a galvanic cell

Nonspontaneous redox reactions can be made to
occur in an electrolytic cell by the addition of
electrical energy.

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 Redox Reactions by the Half-Reaction

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 Galvanic cell or Voltaic cell

The experimental apparatus for generating electricity
through the use of a spontaneous reaction is called a
galvanic cell or voltaic cell, after the Italian scientists
Luigi Galvani and Alessandro Volta, who
constructed early versions of the device.

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 A Spontaneous Redox Reaction:
Zn(s) + Cu2+(aq) → Zn2+ + Cu(s)

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 Electrochemical Cells
Oxidation and reduction half-reactions are kept as separate in
half-cells in an electrochemical cell.

To constitute an electrical circuit:
Electron flow through a wire along with
Ions (electrolyte) flowing through a solution via the salt bridge.

The flow of electrons require a conductive solid electrode to allow
the transfer of electrons either through:
An external circuit or
Metal or graphite electrode

An electrochemical cell requires the exchange of ions between the
two half-cells of the system via a salt bridge.

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 Voltaic (Galvanic) Cells: Spontaneous Redox Reactions

Electrical current: The amount of electric charge that passes a point in a
given period of time
– Whether as electrons flowing through a wire or as ions flowing through
a solution

Redox reactions involve the movement of electrons from one substance to
another.
– Therefore, redox reactions have the potential to generate an
electric current.

Voltaic (galvanic) cells produce an electrical current from spontaneous redox
reactions.
– To use that current, we need to separate the place where oxidation is
occurring from the place where reduction is occurring.

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 Electrodes of an Electrochemical Cell
Anode
– Electrode where oxidation occurs
– Anions attracted to it
– Connected to positive end of battery in an electrolytic cell
– Loses weight in electrolytic cell

Cathode
– Electrode where reduction occurs
– Cations attracted to it
– Connected to negative end of battery in an electrolytic cell
– Gains weight in electrolytic cell
Electrode where plating takes place in electroplating

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 Voltaic Cell

The salt bridge is required to complete the circuit and maintain
charge balance and cell neutrality.
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 Galvanic Cells
Anode:
– The electrode where
oxidation occurs
– The electrode where
electrons are
produced
– Is what anions
migrate toward
– Has a negative sign

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 Galvanic Cells
Cathode:
– The electrode where
reduction occurs
– The electrode where
electrons are
consumed
– Is what cations
migrate toward
– Has a positive sign

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 Cell Notation
Shorthand description of a voltaic cell is written as follows:

electrode | electrolyte || electrolyte | electrode

– Oxidation half-cell on the left; reduction half-cell on
the right
– Single | = phase barrier
If multiple electrolytes in same phase, a comma is
used rather than |
Often use an inert electrode
– Double line || = salt bridge

Example: Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)

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 Voltaic Cell
Anode = Zn(s) Cathode = Cu(s)
The anode is oxidized to Cu2+ ions are reduced at
Zn2+ ions. the cathode.

Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s)
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 https://www.youtube.com/watch?v=qpFC_Ecu_yQ

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 Electrodes
Typically,
– the anode is made of the metal that is oxidized; and
– the cathode is made of the same metal as is produced
by the reduction.

If the redox reaction we are running involves the oxidation
or reduction of an ion to a different oxidation state, or the
oxidation or reduction of a gas, we may use an inert
electrode.
– An inert electrode is one that does not participate in the
reaction but just provides a surface for the transfer of
electrons to take place on.

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 Which Way Will Electrons Flow?
Under standard conditions, zinc has a stronger tendency to oxidize
than copper.
– Electrons flow from anode to cathode.
– Therefore, the electrons flow from zinc, making zinc the anode.

Zn → Zn2+ + 2 e− E° = +0.76
Cu → Cu2+ + 2 e− E° = −0.34

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 Consider the following reaction:
2Ag+(aq)+Cu(s)⇌Cu2+(aq)+2Ag(s)

Write the two half-reactions.

Ag+(aq)+e−⇌Ag(s) Reduction
Cu(s)⇌Cu2+(aq)+2e− Oxidation
Identify the cathode and anode.

Cu(s) is losing electrons thus being oxidized; oxidation occurs at the anode.
Anode (where oxidation occurs):
Ag+ is gaining electrons and thus is being reduced; reduction happens at the cathode.
Cathode (where reduction occurs

Construct the Cell Diagram.

Cu(s)|Cu2+(aq)||Ag+(aq)|
Ag(s)
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 Consider the following two reactions:
 Cu2+(aq)+Ba(s)→Cu(s)+Ba2+(aq)

 2Al(s)+3Sn2+(aq)→2Al3+(aq)+3Sn(s)

Split the reaction into half reactions

a) Ba2+(aq) → Ba(s) + 2e- (Anode; where oxidation happens)
Cu2+(aq) + 2e- → Cu(s) (Cathode; where reduction happens)
b) Al3+(aq) → Al(s) + 3e- (Anode; where oxidation happens)
Sn2+(aq) +2e- → Sn(s) (Cathode; where reduction happens)

Construct a cell diagram for the following each reactions

Ba2+(aq) | Ba(s) || Cu(s) | Cu2+(aq)

Al(s) | Al3+(aq) || Sn2+(aq) | Sn(s)

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 Consider a galvanic cell consisting of
2Cr(s)+3Cu2+(aq)⟶2Cr3+(aq) + 3Cu(s)
Write the oxidation and reduction half-reactions and write the reaction using cell notation.
Which reaction occurs at the anode? The cathode?

By inspection, Cr is oxidized when three electrons are lost to form Cr3+, and
Cu2+ is reduced as it gains two electrons to form Cu. Balancing the charge gives

oxidation:2Cr(s)⟶2Cr3+(aq)+6e−

reduction:3Cu2+(aq)+6e−⟶3Cu(s)

Cell notation uses the simplest form of each of the equations,
Cr(s)∣Cr3+(aq)∥Cu2+(aq)∣Cu(s)Cr

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 Some oxidation-
reduction reactions
involve species that are
poor conductors of
electricity, and so an
electrode is used that
does not participate in
the reactions.
Frequently, the electrode
is platinum, gold, or
graphite, all of which are
inert to many chemical
reactions.

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 Mg(s)+2H+(aq)⟶Mg2+(aq)
+H2(g)

oxidation: Mg(s)⟶Mg2+(aq)
+2e−

reduction:2H+(aq)
+2e−⟶H2(g)

The cell used an inert platinum wire for the
cathode, so the cell notation is
Mg(s)∣Mg2+(aq)∥H+(aq)∣H2(g)∣Pt(s)

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 Write the following balanced reactions using cell
notation. Use platinum as an inert electrode

3CuNO3(aq)
3CuNO3(aq)+Au(NO3)3(aq)⟶3Cu(NO3)2(aq)
+Au(NO3)3(aq)⟶3Cu(NO3)2(aq)+Au(s
+Au(s)
3 Cu0 - 6 e- → 3 CuII (oxidation)
2 AuIII + 6 e- → 2 Au0 (reduction)

Pt(s)∣Cu+(aq),Cu2+(aq)∥Au3+(aq)∣Au(s)

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 Describe in shorthand notation a galvanic cell
for which the cell reaction is

Cu(s)+2Fe3+(aq)→Cu2+(aq)+2Fe2+(aq)

Oxidation: Cu(s)→Cu2+(aq)+2e–
Reduction: Fe3+ +e–→Fe2+

Cu∣Cu2+∥Fe2+,Fe3+∣Pt

Since both Fe2+ and Fe3+ are in solution, a Pt
electrode is used.)

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 Batteries: Leclanché Acidic Dry Cell
Electrolyte in paste form
– ZnCl2 + NH4Cl
or MgBr2

Expensive, nonrechargeable, heavy,
easily corroded

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 Batteries: Alkaline Dry Cell
Same basic cell as acidic dry cell, except
electrolyte is alkaline KOH paste

Longer shelf life than acidic dry cells and
rechargeable, with little corrosion of zinc.

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 Batteries: Lead Storage Battery
Six cells in series

Electrolyte = 30% H2SO4

Rechargeable, heavy

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 NiCad Battery
Electrolyte is concentrated KOH solution.

Rechargeable, long life, light; however, recharging incorrectly
can lead to battery breakdown.

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 Lithium Ion Battery

Electrolyte is concentrated KOH
solution.

Rechargeable, long life, very
light, more environmentally
friendly, greater energy density

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 Fuel Cells
They are like batteries in which
reactants are constantly being added.
– So they never run down!

Anode and cathode are
both Pt coated metal.

Electrolyte is OH– solution.

Anode reaction:
2 H2 + 4 OH– → 4 H2O(l) + 4 e–

Cathode reaction:
O2 + 4 H2O + 4 e– → 4 OH–

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 Electrochemical Cells Overview

In all electrochemical cells, oxidation occurs at the anode and
reduction occurs at the cathode.

In voltaic cells (spontaneous reactions; E°cell is positive),
– the anode is the source of electrons and has a (−) charge;
– the cathode draws electrons and has a (+) charge.

In electrolytic cells (non spontaneous reactions; E°cell is negative),

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 Standard reduction potential (E° or E° red):
Reduction potential for a half-reaction under standard state conditions.
When two half-reactions are connected to the one with the larger (more positive) E° red
goes as a reduction
On the other one (less positive E° red) goes as an oxidation

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 Write the half-cell reaction and the overall cell reaction for the
electrochemical cell: Zn | Zn2+ (1.0M) || Pb2+ (1.0M) | Pb
Calculate the standard e.m.f for the cell if standard electrode potential
(reduction) for Pb2+ | Pb and Zn2+ | Zn electrodes are – 0.126 V and – 0.763 V
respectively

Half reactions are-
Oxidation half-reaction: Zn → Zn2+ +
2e–
Reduction half-reaction: Pb2+ +
2e– → Pb
Overall cell reaction: Zn + Pb2+ →
Zn2+ + Pb
E°cell = E°R – E°L
E°cell = –0.126 – ( –0.763)
E°cell = 0.637 V.
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 Calculate the standard reduction potential of
Ni2+|Ni electrode when the cell potential for the
cell Ni | Ni2+ (1M)|| Cu2+ (1M) | Cu is 0.59 V (E°
Cu2+| Cu = 0.34 V).
Ni | Ni2+ (1M)|| Cu2+ (1M) | Cu

The e.m.f of the cell E°cell =
E°R – E°L

E°cell = E° (Cu2+ | Cu) – E° (Ni |
Ni2+)

0.59 V = 0.34 – E° (Ni | Ni2+)

E° (Ni | Ni2+) = 0.34 – 0.59 = –
0.25 V
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 Electrolysis

Electrolysis is the process of
using electrical energy to
break a compound apart.

Electrolysis is done in an
electrolytic cell.

Electrolytic cells can be used
to separate elements from
their compounds.

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 Electrolysis
In electrolysis we use electrical energy to overcome the
energy barrier of a nonspontaneous reaction, allowing it
to occur.

The reaction that takes place is the opposite of the
spontaneous process.
2 H2(g) + O2(g) → 2 H2O(l) spontaneous
2 H2O(l) → 2 H2(g) + O2(g) electrolysis

Some applications of electrolysis are the following:
(1) Metal extraction from minerals and purification
(2) Production of H2 for fuel cells
(3) Metal plating

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 Electrolytic Cells

The source of energy is a battery or DC power supply.
– The positive terminal of the source is attached to the anode.
– The negative terminal of the source is attached to the cathode.

Electrolyte can be either an aqueous salt solution or a molten ionic salt.

Cations in the electrolyte are attracted to the cathode and anions are
attracted to the anode.

Cations pick up electrons from the cathode and are reduced; anions
release electrons to the anode and are oxidized.

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 Electrolysis and Electrolytic Cells
Electrolysis of Aqueous Sodium Chloride

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 Electrolysis and Electrolytic Cells
Electrolysis of Molten Sodium Chloride

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 Commercial Applications of
Electrolysis
Downs Cell for the Production of Sodium Metal

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 Electroplating

In electroplating, the work piece
is the cathode.

Cations are reduced at
cathode and plate to the
surface of the work piece.

The anode is made of the
plate metal. The anode
oxidizes and replaces the
metal cations in the solution.

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 Commercial Applications of
Electrolysis
Electrorefining of Copper Metal

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 Rusting
At the anodic regions, Fe(s) is oxidized to Fe2+.
The electrons travel through the metal to a cathodic region where
O2 is reduced.
– In acidic solution from gases dissolved in the moisture

The Fe2+ ions migrate through the moisture to the cathodic region,
where they are further oxidized to Fe3+, which combines with the
oxygen and water to form rust.
– Rust is hydrated iron(III) oxide, Fe2O3 · nH2O.
The exact composition depends on the conditions.
– Moisture must be present.
Water is a reactant.
It is required for ion flow between cathodic and anodic regions.

Electrolytes promote rusting.
– They enhance current flow.

Acids promote rusting.
– Lowering pH
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 Corrosion
Corrosion: The oxidative deterioration of a metal

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 Corrosion
Prevention of Corrosion
For some metals, oxidation protects the metal (aluminum,
chromium, magnesium, titanium, zinc, and others). For
other metals, there are two main techniques.

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 Corrosion
Prevention of Corrosion
1. Galvanization: The coating of iron with zinc

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 Corrosion
Prevention of Corrosion
2. Cathodic Protection: Instead of coating the entire surface
of the first metal with a second metal, the second metal is
placed in electrical contact with the first metal:

Attaching a magnesium stake to iron will corrode the
magnesium instead of the iron. Magnesium acts as a
sacrificial anode.

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 Sacrificial Anode

If a metal more active than iron, such as magnesium or aluminum, is
in electrical contact with iron, the metal rather than the iron will be
oxidized. This principle underlies the use of sacrificial electrodes to
prevent the corrosion of iron.
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 Ways to prevent corrosion

passivation (formation of a thin oxide layer by
treatment with an oxidizing agent)
formation of an alloy (stainless steel)
coating with a layer of a less active metal (tin
cans)
cathodic protection (use zinc or magnesium
as a sacrificial metal)

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