Introduction to Material Science and Engineering PDF

Summary

This document provides an introduction to materials science and engineering. It covers different types of materials like metals, ceramics, and plastics. The document also discusses material properties, processing, and structures.

Full Transcript

Introduction to Material Science and
Engineering
 Introduction

Materials Science and Engineering
- a field of engineering that encompasses the spectrum of
materials types and how to use them in manufacturing
 Introduction
Materials Science and Engineering is subdivided
into two:

1. Materials Science
2. Materials Engineering
 Introduction
Material Science
– involves investigating the
relationships that exist between
the structures and properties of
materials

– the role of a materials
scientist is to develop or
synthesize new materials
 Introduction
Materials Engineering
involves, on the basis of these
structure–property correlations,
designing or engineering the
structure of a material to produce a
predetermined set of properties

materials engineer is called upon
to create new products or systems
using existing materials and/or to
develop techniques for processing
materials
 Introduction
Materials

Generic categories of materials
¤ Metals
¤ Ceramics
¤ Plastics
¤ Semiconductors
¤ Composites
 Introduction
Metals

Metals are materials that are normally combinations of "metallic
elements".
These elements, when combined, usually have electrons that are
non-localized and as a consequence have generic types of
properties.
Metals usually are good conductors of heat and electricity. They
are also quite strong but deformable and tend to have a lustrous
look when polished.
 Introduction
Ceramics

Ceramics are generally compounds between metallic and
nonmetallic elements and include such compounds as oxides,
nitrides, and carbides.

Typically they are insulating and resistant to high temperatures
and harsh environments.
 Introduction
Plastics

Plastics, also known as polymers, are generally organic
compounds based upon carbon and hydrogen.

They are very large molecular structures.

Usually they are low density and are not stable at high
temperatures.
 Introduction
Semiconductors
Semiconductors have electrical properties intermediate
between metallic conductors and ceramic insulators.

Electrical properties are strongly dependent upon small
amounts of impurities.
 Introduction
Composites
Composites consist of more than one material type.

Fiberglass, a combination of glass and a polymer, is an example.
Concrete and plywood are other familiar composites.

Many new combinations include ceramic fibers in metal or polymer
matrix.
 Introduction
Four Elements of the Field
Processing
Structure
Property
Performance
 the structure of a material depends on how it is processed
structure of a material usually relates to the
arrangement of its internal components
– Microscopic – cannot be seen by naked eye
– Macroscopic – large enough to be seen by naked eyes
a material’s performance is a function of its properties
all materials are exposed to external stimuli that evoke
some type of response
 Example
These are ingots. Both are made
from Silicon which were
extracted from sand. The two
materials are used in different
ways. Ingot A is usually used in
calibration while Ingot B is
usually used in making
semiconductor materials such as
integrated circuits.

Performance of materials will depend on the properties it
has. The properties will depend on the atomic structure
formulated and how it was processed.
 Introduction
Processing

Solidification Processing
Powder processing
Deposition processing
Deformation Processing
 Introduction
Solidification Processing
Most metals are formed by creating an alloy in the molten state, where
it is relatively easy to mix the components. This process is also utilized
for glasses and some polymers.

Once the proper temperature and composition have been achieved,
the melt is cast.
 Introduction
Powder Processing

Powder processing involves consolidation, or packing, of particulate to
form a `green body'. Densification follows, usually by sintering.

There are two basic methods of consolidating powders:
- dry-pressing - dry powder can be compacted in a die,
- slip-casting or filter pressing - the particles can be suspended in a
liquid and then filtered against the walls of a porous mold
 Introduction
Powder Processing

Bulk ceramics are usually processed in powder form since their high
melting points and low formability prohibit other types of processing.
Metals and polymers can also be processed from powders.
 Introduction
Deposition Processing

Deposition processing modifies a surface chemically, usually by
depositing a chemical vapor or ions onto a surface.

It is used in semiconductor processing and for decorative or protective
coatings.

Vapor source methods require a vacuum to transport the gaseous
source of atoms to the surface for deposition.
 Introduction
Deposition Processing

Common vapor sources are thermal evaporation (similar to boiling
water to create steam), sputtering (using energetic ions to bombard a
source and create the gas state), or laser light (ablates, or removes,
atoms from surface to create the gaseous state).

Other sources use carrier media such as electrochemical mixtures (ions
in a solution transported by an electrical field to the surface for
depositions) or spray coating (ions or small particles transported by
gases, liquids, and/or electrical field).
 Introduction
Deformation Processing

One of the most common processes is the deformation of a solid to
create a desired shape. A large force is generally used to accomplish the
deformation, and many techniques heat the material in order to reduce
the force necessary to deform it.

Sometimes a mold is used to define the shape. Forging, an old method
that heated the metal and deformed the metal by hammer blows is still
used today, albeit with multi-ton hammers.
 Introduction
Deformation Processing

Rolling to reduce the thickness of a plate is another common process.
Some glasses when heated can be formed with tools or molds.

Other common methods, like drilling to make holes, or milling, are
machining versions of the deformation process.
 Introduction
Structure
Structure refers to the arrangement of a material's components
from an atomic to a macro scale.

Understanding the structure of a substance is key to understanding
the state or condition of a material, information which is then
correlated with the processing of the material in tandem with its
properties.
Understanding these relationships is an intrinsic part of materials
science engineering, as it allows engineers to manipulate the
properties of a material.
 Introduction
Properties

Materials engineers must frequently reconcile the desired
properties of a material with its structural state to ensure
compatibility with its selected processing.
 Properties of solid materials
Important properties of solid materials may be grouped into
six different categories:

1. Mechanical
– relate deformation to an applied load or force include elastic modulus
(stiffness), tensile strength, fracture toughness, fatigue strength, creep
strength, hardness

2. Electrical
– such as electrical conductivity and dielectric constant, the stimulus is
an electric field
– Conductivity or resistivity, ionic conductivity, semiconductor
conductivity (mobility of holes and electrons)
 Properties of solid materials
3. Thermal
– can be represented in terms of heat capacity, thermal conductivity,
and coefficient of thermal expansion

4. Magnetic
– demonstrate the response of a material to the application of a
magnetic field
– Magnetic susceptibility, Curie Temperature, Neel Temperature,
saturation magnetization
 Properties of solid materials
5. Optical
– the stimulus is electromagnetic or light radiation; index of
refraction and reflectivity are representative optical properties
– Polarization, capacitance, permittivity, refractive index,
absorption
6. Deteriorative
– relate to the chemical reactivity of materials
– corrosion behavior, wear behavior
 Properties of Materials
1. Chemical Properties
2. Physical Properties
3. Mechanical Properties
4. Dimensional Properties
 Chemical Properties
These are properties of a material that refer to the
structure of a material and its formation from our
elements.

The chemical properties of a material include
composition, corrosion resistance, crystal structure,
microstructure, and stereospecificity
 Chemical Properties
Composition - is the elemental or chemical components
of the material and the relative proportion of these
components In metals, composition usually means the
percentage of the various elements that make up the
metal.
Corrosion resistance - is the ability of the material to
resists deterioration by chemical or electro-chemical
reaction with its environment.
 Chemical Properties
Crystal structure - is the ordered, repeating arrangement of
atoms and molecules in a material.
Microstructure - is the structure of polished and etched materials
as revealed by microscope magnifications greater than ten
diameters.
Stereospecificity - is the tendency for polymers and molecular
materials to form with an ordered, spatial, three-dimensional
arrangement of monomer molecules.
 Physical Properties
These are properties of materials that refer to the
interaction of materials with various forms of energy and
with other forms of matter.

The physical properties of a material include Curie point,
density, dielectric strength, electrical resistivity, heat
distortion temperature, melting point, Poisson’s ratio,
refractive index, specific gravity, thermal conductivity,
and thermal expansion.
 Physical Properties
Curie point - is the temperature at which ferromagnetic
materials can no longer be magnetized by outside forces.
Density - is the mass per unit volume.
Dielectric strength - is the maximum potential difference that
an insulating material of given thickness can withstand for a
specified time without occurrence of electrical breakdown
through its bulk.
 Physical Properties
Electrical resistivity - is the electrical resistance of a material
per unit length and cross-sectional area or per unit length and
unit weight.
Heat distortion temperature - is the temperature at which a
polymer under a specified load shows a specified amount of
deflection.
Melting point - is the point at which a material liquefies on
heating or solidifies on cooling.
 Physical Properties
Poisson's ratio - is the absolute value of the ratio of the
transverse strain to the corresponding axial strain in a body
subjected to uniaxial stress.

Refractive index - is the ratio of the velocity of light in a vacuum
to its velocity in another material.

Specific gravity - is the ratio of the mass or weight of a solid or
liquid to the mass or weight of an equal volume of water.
Specific gravity of water is 1.000 at 4C.
 Physical Properties
Thermal conductivity - is the rate of heat flow per unit time in a
homogeneous material under steady-state conditions, per unit
area, per unit temperature gradient in a direction perpendicular
to area.

Thermal expansion - is the rate at which a material elongates
when heated.
 Mechanical Properties
These are properties of a material that are displayed when a
force is applied to the material.

These include compressive strength, creep, creep strength,
endurance limit, flexural strength, hardness, modulus of
elasticity, percent elongation, percent reduction in area, shear
strength, and yield strength.
 Mechanical Properties
Compressive strength - is the maximum compressive stress that
a material is capable of withstanding.
Creep - is the permanent strain under strain.
Creep strength - is the constant nominal stress that will cause a
specified quantity of creep in a given time of constant
temperature.
Endurance limit - the maximum stress below which a material
can theoretically endure an infinite number of stress cycles.
 Mechanical Properties
Flexural strength - is the outer fiber stress developed when a
material is loaded as a simple supported beam and deflected to
a certain value of strain.
Hardness - is the resistance of a material to plastic deformation.
Modulus of elasticity - is the ratio. of stress to strain in a
material loaded within its elastic range. It is a measure of
rigidity. It is also known as Young's Modulus. The modulus of
elasticity of steel is 200,000 MPa..
 Mechanical Properties
Percent reduction in area - is the difference (expressed as a
percentage of original area) between the original cross-sectional
area of a tensile test specimen and the minimum cross-sectional
area measured after fractures.
Shear Strength – is the stress required to fracture a shape in a
cross-sectional plane that is parallel to the force application
Yield Strength – is the stress at which a material exhibits a
specified deviation from proportionality of stress and strain.
 Dimensional Properties
Camber - is the deviation from edge straightness. It is usually
the maximum deviation of an edge from a straight line of given
length.

Lay - is the direction of a predominating surface pattern. It is
usually after a machine operation.

Out of flat - is the deviation of a surface from a flat plane,
usually over a macroscopic area.
 Dimensional Properties
Roughness - is relatively finely spaced surface in regularities,
the height, width and direction of which establish a definite
surface pattern.

Surface finish - is the microscopic and macroscopic
characteristics that describe a surface.

Waviness - a wavelike variation from a perfect surface.
 Introduction
Performance
The evaluation of performance is an integral part of the field.

The analysis of failed products is often used to obtain feedback on processing
and its control as well as to assist in the initial selection of the material and in
the stages of processing.

Testing also ensures that the product meets performance requirements.

In many products the control of its processing is closely associated with some
property test and/or a structural characterization.
 Material Selection
Criteria need in material selection
1. in-service conditions to which the material will be
subjected
2. any deterioration of material properties during
operation
3. economics or cost of the fabricated piece
END
Classification of Solid Materials
 Classification of Solid Materials
Solid materials have been conveniently grouped into three
basic categories: metals, ceramics, and polymers, a scheme
based primarily on chemical makeup and atomic structure.
Most materials fall into one distinct grouping or
another. In addition, there are the composites that are
engineered combinations of two or more different
materials.
 Metals
Metals are composed of
one or more metallic
elements, and often also
nonmetallic elements in
relatively small amounts

Atoms in metals and their alloys are
arranged in a very orderly manner
and are relatively dense in
comparison to the ceramics and
polymers
 Metals
With regard to mechanical
characteristics, these materials
are relatively stiff and strong, yet
are ductile, and are resistant to
fracture, which accounts for their
widespread use in structural
applications.

Metallic materials have large
numbers of nonlocalized
electrons—that is, these
electrons are not bound to
particular atoms.
 Ceramics
Ceramics are compounds between
metallic and nonmetallic
elements; they are most
frequently oxides, nitrides, and
carbides.

Common ceramic materials include:
– aluminum oxide (or alumina, Al2O3)
– silicon dioxide (or silica, SiO2)
– silicon carbide (SiC),
– silicon nitride (Si3N4)
– traditional ceramics
those composed of clay minerals as well
as cement and glass.
 Ceramics
ceramic materials are
relatively stiff and strong—
stiffness and strengths are
comparable to those of the
metals
they are typically very hard
ceramics have exhibited
extreme brittleness (lack of
ductility) and are highly
susceptible to fracture
 Ceramics
Ceramic materials are typically
insulative to the passage of heat
and electricity and are more
resistant to high temperatures
and harsh environments than
are metals and polymers.

With regard to optical
characteristics, ceramics may be
transparent, translucent, or
opaque, and some of the oxide
ceramics exhibit magnetic
behavior.
 Polymers
Polymers include the familiar
plastic and rubber materials.

Many of them are organic
compounds that are chemically
based on carbon, hydrogen, and
other nonmetallic elements (i.e., O,
N, and Si).

Furthermore, they have very
large molecular structures, often
chainlike in nature, that often
have a backbone of carbon
atoms.
 Polymers
Some common and familiar polymers are:
polyethylene (PE)
Nylon
poly(vinyl chloride) (PVC)
polycarbonate (PC)
polystyrene (PS)
silicone rubber.
 Polymers
These materials typically have low densities whereas their
mechanical characteristics are generally dissimilar to those of the
metallic and ceramic materials
Polymers are extremely ductile and pliable, which means they are
easily formed into complex shapes.
One major drawback to the polymers is their tendency to soften
and/or decompose at modest temperatures, which, in some
instances, limits their use.
They have low electrical conductivities and are nonmagnetic.
 Composites
The design goal of a composite is to achieve a combination of properties that is
not displayed by any single material and also to incorporate the best
characteristics of each of the component materials.

A large number of composite types are represented by different
combinations of metals, ceramics, and polymers.
 Composites
One of the most common and familiar composites is fiberglass,
in which small glass fibers are embedded within a polymeric
material.

Another is the carbon fiber–reinforced polymer (CFRP)
composite— carbon fibers that are embedded within a polymer.
– CFRP composites are used in some aircraft and aerospace applications, as
well as in high-tech sporting equipment and recently in automobile
bumpers.
END
Advanced Materials
 Advanced Materials
Materials utilized in high-technology (or high- tech)
applications are sometimes termed advanced
materials.
Includes:
– Semiconductors
– Biomaterials
– Smart materials
– Nanomaterials
 Semiconductors
Semiconductors have electrical properties that are
intermediate between the electrical conductors and
insulators.

Furthermore, the electrical characteristics of these
materials are extremely sensitive to the presence of minute
concentrations of impurity atoms, for which the
concentrations may be controlled over very small spatial
regions.
 Semiconductors
Semiconductors have made
possible the advent of
integrated circuitry that has
totally revolutionized the
electronics and computer
industries over the past Integrated Circuit (IC)
three decades.
 Biomaterials
Biomaterials are employed in
components implanted into the
human body for replacement of
diseased or damaged body parts.
Artificial total hip
These materials must not replacement
produce toxic substances and
must be compatible with body
tissues
 Smart Materials
These are a group of new and state-of-the-art materials now being
developed that will have a significant influence on many of our
technologies.
The adjective “smart” implies that these materials are able to sense
changes in their environments and then respond to these changes in
predetermined manners
Components of a smart material (or system) include some type of sensor
(that detects an input signal), and an actuator (that performs a
responsive and adaptive function).
 Smart Materials
Four types of materials are commonly used for
actuators:
– shape memory alloys
– piezoelectric ceramics
– magnetostrictive materials
– electrorheological/magnetorheological fluids.
 Smart Materials
Shape memory alloys
Are metals that after having been deformed, revert
back to their original shapes when temperature is
changed.

Piezoelectric ceramics
Piezoelectric ceramics expand and contract in response to an
applied electric field (or voltage); conversely, they also
generate an electric field when their dimensions are altered
 Smart Materials
Magnetostrictive
materials is analogous to that of the piezoelectrics, except that they
are responsive to magnetic fields.

Electrorheological and magnetorheological fluids
are liquids that experience dramatic changes in viscosity upon the
application of electric and magnetic fields, respectively.
 Nanoengineered Materials
Materials that are not distinguished on the basis of their
chemistry but rather their size
The nano prefix denotes that the dimensions of these
structural entities are on the order of a nanometer (10-9
m)—as a rule, less than 100 nanometers (nm;
equivalent to the diameter of approximately 500
atoms).
END
Material Science and
Engineering
Atomic Structure
 Atomic Structure
Each atom consists of a very small nucleus composed of
protons and neutrons and is encircled by moving electrons

Electron Charge:

p and e = ± 1.602x10-19 C

n = neutral charge
 Atomic Structure
Each chemical element is characterized by the
number of protons in the nucleus, or the atomic
number (Z)

Example:
Hydrogen = 1
Uranium = 92
 Atomic Structure
The atomic mass (A) of a specific atom may be
expressed as the sum of the masses of protons
and neutrons within the nucleus.
≅ +

Where:
Proton & Neutron mass = 1.67x10-27 kg
A = Atomic Mass Electron mass = 9.11x10-31 kg
Z = Atomic Number
N = Number of Neutrons
 Atomic Structure
Number of protons is the same
for a given element but
number of neutrons may vary.

Atoms of some elements have
two or more different atomic
masses, which are called
isotopes.
 Atomic Structure
The atomic weight of an element or the molecular weight of a
compound may be specified on the basis of amu per atom (molecule)
or mass per mole of material

In one mole of a substance, there are 6.022x1023 (Avogadro’s
number) atoms or molecules.

1 amu/atom (or molecule) = 1 g/mol Example:
atomic weight of iron is 55.85 amu/atom, or 55.85 g/mol
 Atomic Structure
Example
Cerium has four naturally occurring isotopes: 0.185% of
136Ce, with an atomic weight of 135.907 amu; 0.251% of
138Ce, with an atomic weight of 137.906 amu; 88.450% of
140Ce, with an atomic weight of 139.905 amu; and 11.114%
of 142Ce, with an atomic weight of 141.909 amu.
Calculate the average atomic weight of Ce.
Ans. 140.115 amu
 Atomic Structure
Example:
Silicon has three naturally occurring isotopes:
92.23% of 28Si, with an atomic weight of 27.9769 amu;
4.68% of 29Si, with an atomic weight of 28.9765 amu; and
3.09% of 30Si, with an atomic weight of 29.9738 amu.
Calculate the average atomic weight of Si.

Ans. 28.0854 amu
Material Science and
Engineering

Atomic Models
 Electrons in Atoms

During the latter part of the nineteenth century,
it was realized that many phenomena involving
electrons in solids could not be explained in terms
of classical mechanics.
 Electrons in Atoms
Quantum mechanics
A set of principles and laws that govern systems of
atomic and subatomic entities
An understanding of the behavior of electrons in
atoms and crystalline solids necessarily involves the
discussion of quantum-mechanical concepts.
 Electrons in Atoms
Two atomic models
1. Bohr Atomic Model
2. Wave – Mechanical Model
 Bohr Atomic Model

Electrons are assumed to
revolve around the atomic
nucleus in discrete orbitals,
and the position of any
particular electron is more or
less well defined in terms of its
orbital
 Wave-mechanical model

Electron is considered to exhibit both wavelike
and particle-like characteristics.
With this model, an electron is no longer treated as a
particle moving in a discrete orbital; rather, position is
considered to be the probability of an electron’s being at
various locations around the nucleus (electron cloud)
 Quantum Numbers
In wave mechanics (quantum mechanics),
every electron in an atom is characterized by
four parameters called quantum numbers.
Bohr energy levels separate into electron subshells,
and quantum numbers dictate the number of states
within each subshell
 Quantum Numbers
Shells are specified by a principal
quantum number (n)
– Designated by letter K, L, M, N, O, etc..
– Which also corresponds to n = 1, 2, 3, 4,
etc..

This quantum number is related to the size of an
electron’s orbital or its average distance from the nucleus.
 Quantum Numbers
The second quantum number is angular quantum
number (l). It is related to the shape of the electron
subshell. In addition, the number of these subshells is
restricted by the magnitude of n. Values of l are
integer values that range from
l = 0 to l = n-1
 Quantum Numbers
Each subshell is denoted by a lowercase letter—
an s, p, d, or f—related to l values as follows
 Quantum Numbers

The angular quantum number is
very important since it specifies
the shape of an atomic orbital and
strongly influences chemical
bonds and bond angles.
 Quantum Numbers
The third (magnetic) quantum number describes the energy levels available
within a subshell and yields the projection of the orbital angular momentum
along a specified axis. The values of mℓ range from − to ℓ, with integer steps
between them.
Third (or magnetic) quantum number (ml) integer values between - ℓ to + ℓ,
When
ℓ = 0; then ml=0 = 0
ℓ = 1; then ml=1 = -1,0,+1
ℓ = 2; then ml=2 = -2,-1,0,+1,+2
ℓ = 3; then ml=3 = -3,-2-1,0,+1,+2,+3
 Quantum Numbers
Fourth Quantum Number is the Spin Moment
It describes the spin (intrinsic angular momentum) of the
electron within that orbital and gives the projection of the
spin angular momentum (s) along the specified axis.
+ 1/2 (for spin up) and – 1/2 (for spin down)

Example:
Find the Spin of Neon
Ans. - 1/2
 Example
Find the quantum number of:
a) Sodium(Na)
b) Cobalt(Co)

Ans.
Na = (3,0,0,1/2)
Co = (3,2,-1,-1/2)
Material Science and
Engineering

Atomic Bonding in Solids
 Atomic Bonding in Solids

Bonding Energy – the energy required to separate two atoms
that are chemically bonded to each other. It may be expressed
on per atom basis or per mole of atoms
 Atomic Bonding in Solids
Primary Bond – Three different types of primary or
chemical bond are found in solids ─ ionic, covalent and
metallic.

Each of these three types of bonding arises from the
tendency of the atoms to assume stable electron
structures, like those of the inert gases, by completely filling
the outermost electron shell.
 Primary Interatomic Bonds
Ionic Bonding – it is always found in compounds that are composed of both metallic
and non metallic elements, elements that are situated at the horizontal extremities of
the periodic table
 Primary Interatomic Bonds
Covalent Bonding - stable electron configurations are assumed by the sharing of
electrons between adjacent atoms. Two atoms that are covalently bonded will each
contribute at least one electron to the bond, and the shared electrons may be
considered to belong to both atoms
 Primary Interatomic Bonds
Metallic Bonding – the final primary bonding type, is found in metals and their alloys.
Metallic materials have one, two, or at most, three valence electrons. With these
model, these valence electron are not bound to any particular atom in the solid and
are more or less free to drift throughout the entire metal.
 Secondary Bonding or Van der Waals Bonding
Secondary Bonding – are weak in comparison to the primary or chemical ones;
bonding energies are typically on the order of only 10 kJ/mol (0.1 eV/atom)

Dipole – a pair of equal yet opposite electrical charges that are separated by a
small distance

Hydrogen Bonding – a special type of secondary bonding, is found to exist
between some molecules that have hydrogen as one of the constituents

Polar Molecule – a permanent dipole exist in some molecules by virtue of an
asymmetrical arrangement of positively and negatively charged regions
 Bonding Energies and Melting Temperature
for Various Substances
Bonding Type Substance kJ/mol eV/atom, Ion, Melting
molecule Temperature
(degree C)
Ionic NaCl 640 3.3 801
MgO 1000 5.2 2800
Covalent Si 450 4.7 1410
C (Diamond) 713 7.4 > 3550
Metallic Hg 68 0.7 -39
Al 324 3.4 660
Fe 406 4.2 1538
W 849 8.8 3410
Van der Waals Ar 7.7 0.08 -189
31 0.32 -101
35 0.36 -78
Hydrogen 51 0.52 0
END
Material Science and
Engineering

Structures of Crystalline Solids
A. Atomic Structure in Solids
B. Crystal Structures
 UNIT CELL
- The unit cell is building block for crystal.
- Repetition of unit cell generates entire crystal.
 Metallic Crystal Structures
Tend to be densely packed
Several reasons for dense packing:
-Typically, only one element is present, so all atomic
radii are the same.
-Metallic bonding is not directional.
-Nearest neighbor distances tend to be small in order
to lower bond energy.
Have the simplest crystal structures. 74 elements
have the simplest crystal structures – BCC, FCC and HCP
 Metallic Crystals
Three simple lattices that describe metals are
- Face Centered Cubic (FCC)
- Body Centered Cubic (BCC)
- Hexagonal Close Packed (HCP)
 Simple Cubic Structure
Rare due to poor packing (only
Po has this structure) Coordination # = 6
Close-packed directions are (# nearest neighbors)

cube edges.
 BODY CENTERED CUBIC STRUCTURE (BCC)
Atoms touch each other along cube diagonals.
Note: All atoms are identical; the center atom is shaded differently only for ease of viewing.
ex: Cr, W, Fe (a), Tantalum, Molybdenum

Coordination # = 8
 FACE CENTERED CUBIC STRUCTURE (FCC)

Atoms touch each other along face diagonals.
--Note: All atoms are identical; the face-centered atoms are shaded
differently only for ease of viewing.
ex: Al, Cu, Au, Pb, Ni, Pt, Ag
Coordination # = 12
 HEXAGONAL CLOSE-PACKED STRUCTURE (HCP)
ABAB... Stacking Sequence
3D Projection 2D Projection

A sites

B sites

A sites

Coordination # = 12
APF = 0.74
 DENSITIES OF MATERIAL CLASSES
rmetals rceramics rpolymers
Why?
Metals have...
close-packing
(metallic bonding)
large atomic mass
Ceramics have...
less dense packing
(covalent bonding)
often lighter elements
Polymers have...
poor packing
(often amorphous)
lighter elements (C,H,O)
Composites have...
intermediate values Data from Table B1, Callister 6e.
13
 DEMO: HEATING AND COOLING
OF AN IRON WIRE
The same atoms can
Demonstrates "polymorphism" have more than one
crystal structure.

19
C. CRYSTALLOGRAPHIC POINTS,
DIRECTIONS, AND PLANES
Recall: Three-dimensional
Graph Recall: Three-dimensional Graph
Crystallographic Planes & Directions
 Crystallographic Planes & Directions
It is often necessary to be able to specify certain
directions and planes in crystals.

Many material properties and processes vary with
direction in the crystal.

Directions and planes are described using three
integers - Miller Indices
Crystallographic Direction
Crystallographic Planes
D. CRYSTALLINE AND NON-
CRYSTALLINE MATERIALS
 CRYSTALLINE MATERIALS

- the state of a solid material characterized by a
periodic and repeating three-dimensional array of
atoms, ions, or molecules.
 NON-CRYSTALLINE MATERIALS
- the solid state wherein there is no long-range
atomic order.

- also known as Amorphous Solids.
 CRYSTALLINE vs NON-CRYSTALLINE
CRYSTALLINE: NON-CRYSTALLINE:
They have characteristic In these solids particles are
geometrical shape. randomly arranged in three
They have highly ordered three- dimension.
dimensional arrangements of They don’t have sharp melting
particles. points.
They are bounded by PLANES or Amorphous solids are formed
FACES due to sudden cooling of
Planes of a crystal intersect at liquid.
particular angles. Amorphous solids melt over a
They have sharp melting and wide range of temperature
boiling points.
 CRYSTALLINE

Copper Sulfate (CuSO4) Diamond

Graphite Nickel Sulfate (NiSO4)
 NON-CRYSTALLINE

Glass Plastic

Rubber Paraffin
 MATERIALS AND PACKING
Crystalline materials...
atoms pack in periodic, 3D arrays
typical of: -metals
-many ceramics
-some polymers crystalline SiO2
Adapted from Fig. 3.18(a),
Callister 6e.

Noncrystalline materials...
atoms have no periodic packing
occurs for: -complex structures
-rapid cooling
"Amorphous" = Noncrystalline noncrystalline SiO2
Adapted from Fig. 3.18(b),
Callister 6e.

26
 GLASS STRUCTURE
Basic Unit: Glass is amorphous
4- Amorphous structure
Si04 tetrahedron occurs by adding impurities
Si4+ (Na+,Mg2+,Ca2+, Al3+)
O2-
Impurities:
interfere with formation of
crystalline structure.

Quartz is crystalline
SiO2:

(soda glass)
Adapted from Fig. 12.11,
Callister, 6e.

28
 CRYSTALLINE MATERIAL:
SINGLE CRYSTAL
Also called MONOCRYSTALLINE solid.

A crystalline material in which there is long-range
order. Such a material has no grain boundaries, so it is
completely uniform throughout the entire crystal,
regardless of its size.

Can be produced naturally and artificially.
 CRYSTALLINE MATERIAL:
SINGLE CRYSTAL
Occurs when the periodicity in crystal pattern extends
throughout a certain piece of materials.

Many types of single crystal exhibit ANISOTROPY (Properties
of a material that depends on the direction)

A single crystal is formed by the growth of a crystal nucleus
without secondary nucleation or impingement on other
crystals.
 CRYSTALLINE MATERIAL:
POLYCRYSTALLINE
A collection of many small crystals or grains.

Has the characteristic called POLYMORPHISM (The ability of a
solid material to exist in more than one form or crystal
structure)

Occurs when the periodicity in the crystal structure is
interrupted at so-called grain boundaries.
 CRYSTALLINE MATERIAL:
POLYCRYSTALLINE

The size of the grains or crystallites is smaller than the size of
the pattern unit which forms the periodicity.

In general, the grains in such a solid are not related in shape
to the crystal structure, the surface being random in shape
rather than well defined crystal planes
POLYCRYSTALS
Most engineering materials are polycrystals.

Adapted from Fig. K,
color inset pages of
Callister 6e.
(Fig. K is courtesy of
Paul E. Danielson,
Teledyne Wah Chang
Albany)
1 mm

Nb-Hf-W plate with an electron beam weld.
Each "grain" is a single crystal.
If crystals are randomly oriented,
overall component properties are not directional.
Crystal sizes typ. range from 1 nm to 2 cm
(i.e., from a few to millions of atomic layers).
SINGLE VS POLYCRYSTALS
Single Crystals
-Properties vary with
direction: anisotropic.
-Example: the modulus
of elasticity (E) in BCC iron:

Polycrystals
-Properties may/may not 200 µm
vary with direction.
-If grains are randomly
oriented: isotropic.
(Epoly iron = 210 GPa)
-If grains are textured,
anisotropic.
END
Crystalline and Noncrystalline Materials
part 1
 Introduction
Previous discussion was concerned primarily
with the various types of atomic bonding, which
are determined by the electron structures of the
individual atoms.
This discussion is devoted to the next level of the
structure of materials, specifically, to some of the
arrangements that may be assumed by atoms in the
solid state.
 Introduction
Two concepts in the arrangement of atoms:
1. Crystalline Structure
2. Noncrystalline Structure
 Crystalline Structure
crystalline material is one in which
the atoms are situated in a repeating
or periodic array over large atomic
distances.
That is, long-range order exists, such
that upon solidification, the atoms
will position themselves in a
repetitive three-dimensional pattern,
in which each atom is bonded to its
nearest neighbor atoms.
 Noncrystalline Structure
Also called amorphous
long-range atomic order is absent
 Crystalline Structure
Atomic hard-sphere model -
atoms are thought of as
being solid spheres having
well-defined diameter.
Lattice - a three-dimensional
array of points coinciding
with atom positions
 Crystalline Structure

Unit Cell - the smallest group
of atoms of a substance that
has the overall symmetry of a
crystal of that substance, and
from which the entire lattice
can be built up by repetition
in three dimensions.
 Metal Crystal Structure
Three crystal structure found on metals:
1. Face-centered cubic
2. Body-centered cubic
3. Hexagonal close-packed
Continue at part 2
Crystalline and Noncrystalline Materials
part 2
 Face-centered cubic crystal structure
Atoms located at each
corners and the center of
all the cube faces
Cube edge length “a” and
the atomic radius R are
related through
𝑎 = 2𝑅 2
 Face-centered cubic crystal structure
The number of atoms per unit
cell may computed using the
following formula:
𝑁𝑓 𝑁𝑐
𝑁 = 𝑁𝑖 + +
2 8
Where:
Ni = no. of interior atoms
Nf = no. of face atoms
Nc = no. of corners of atom
 Face-centered cubic crystal structure
Two other important characteristics of a crystal
structure:
1. Coordination number
2. Atomic packing factor
 Face-centered cubic crystal structure
Coordination number
For metals, each atom has
the same number of
nearest-neighbor or
touching atoms
For FCC, the coordination
number is 12.
 Face-centered cubic crystal structure
Atomic packing factor
is the sum of the sphere volumes of all atoms within a unit
cell (assuming the atomic hard-sphere model) divided by the
unit cell volume
𝑣𝑜𝑙𝑢𝑚𝑒 𝑜𝑓 𝑎𝑡𝑜𝑚𝑠 𝑖𝑛 𝑎 𝑢𝑛𝑖𝑡 𝑐𝑒𝑙𝑙
𝐴𝑃𝐹 =
𝑡𝑜𝑡𝑎𝑙 𝑢𝑛𝑖𝑡 𝑐𝑒𝑙𝑙 𝑣𝑜𝑢𝑙𝑚𝑒

For FCC, atomic packing factor is 0.74 which is the maximum
packing possible for spheres all having the same parameters
 Face-centered cubic crystal structure
Example:
Calculate the volume of an FCC unit cell in terms of
the atomic radius R.

Ans. 16R3 2
 Face-centered cubic crystal structure
Example:
Show that the atomic packing factor for the FCC crystal
structure is 0.74

Ans.
16 3
𝑉𝑠𝑝ℎ𝑒𝑟𝑒 𝜋𝑅
3
𝐴𝑃𝐹 = = = 0.74
𝑉𝑐𝑢𝑏𝑒 16𝑅3 2
Body-Centered Cubic Crystal Structure
has a cubic unit cell with
atoms located at all eight
corners and a single atom
at the cube center
unit cell length a and
atomic radius R are related
through
4𝑅
a=
3
Body-Centered Cubic Crystal Structure
The number of atoms per
BCC may computed using
the following formula:
𝑁𝑓 𝑁𝑐
𝑁 = 𝑁𝑖 + +
2 8
Where:
Ni = no. of interior atoms
Nf = no. of face atoms
Nc = no. of corners of atom
Body-Centered Cubic Crystal Structure
The coordination
number for the BCC
crystal structure is 8
the atomic packing factor
is also lower for BCC is
0.68
Body-Centered Cubic Crystal Structure
It is also possible to have a
unit cell that consists of
atoms situated only at the
corners of a cube. This is
called the simple cubic (SC)
crystal structure
The only simple-cubic
element is polonium,
which is considered to be a
metalloid (or semi-metal)
Crystalline and Noncrystalline Materials
part 3
 Hexagonal Close-Packed Crystal Structure
The top and bottom faces of
the unit cell consist of six
atoms that form regular
hexagons and surround a
single atom in the center.
Another plane that provides
three additional atoms to the
unit cell is situated between
the top and bottom planes.
Hexagonal Close-Packed Crystal Structure
The number of atoms per HCP may computed using
the following formula:
𝑁𝑓 𝑁𝑐
𝑁 = 𝑁𝑖 + +
2 6
2 12
𝑁 =3+ +
2 6
𝑁=6
 Hexagonal Close-Packed Crystal Structure
c/a ratio should be 1.633
coordination number and
the atomic packing factor
for the HCP crystal structure
are the same as for FCC: 12
and 0.74, respectively
Hexagonal Close-Packed Crystal Structure
Example:
Calculate the volume of an HCP unit cell in terms of
its a and c lattice parameters.
Now provide an expression for this volume in terms
of the atomic radius, R, and the c lattice parameter
 Density Computation
A knowledge of the crystal structure of a metallic solid
permits computation of its theoretical density 𝜌 through the
relationship
𝑛𝐴
𝜌=
𝑉𝑐 𝑁𝐴
Where:
n – no. of atoms associated with each unit cell
A – atomic weight
Vc – volume of unit cell
NA – Avogadro’s number (6.022x1023 atom/mol)
 Density Computation
Example:
Copper has an atomic radius of 0.128 nm, an FCC crystal
structure, and an atomic weight of 63.5 g/mol. Compute its
theoretical density, and compare the answer with its measured
density.
Ans.
8.89 g/cm3
The literature value for the density of copper is 8.94 g/cm3,
which is in very close agreement with the foregoing result.
 Polymorphism and Allotropy
phenomenon on metals, as well as nonmetals to have
more than one crystal structure is known as
polymorphism.
When found on solids, the condition is termed as
allotropy
Graphite is the stable polymorph at ambient
temperature
Diamond formed at extremely high pressure
Pure iron has a BCC crystal structure at room
temperature which changes to FCC at 912℃.
 Crystal Systems
Because there are many different possible crystal
structures, it is sometimes convenient to divide them
into groups according to unit cell configurations and/or
atomic arrangements.
One such scheme is based on the unit cell geometry
The unit cell geometry is completely defined in terms of
six parameters: the three edge lengths a, b, and c, and
the three interaxial angles 𝛼, 𝛽, and 𝛾 which is
sometimes termed as lattice parameters.
END
3.1 Impurities in Solids

Why study Imperfections in Solids?

The properties of some materials are profoundly influenced by the presence of imperfections.
Consequently, it is important to have a knowledge about the types of imperfections that exist and
the roles they play in affecting the behavior of materials.

For example, the mechanical properties of pure metals experience significant alterations when the
metals are alloyed (i.e., when impurity atoms are added)—for example, brass (70% copper/30%
zinc) is much harder and stronger than pure copper.

Also, integrated-circuit microelectronic devices found in our computers, calculators, and home
appliances function because of highly controlled concentrations of specific impurities that are
incorporated into small, localized regions of semiconducting materials.

For this module, we are going to deal with the imperfections and defects. But what really are
these?

It has been tacitly assumed that perfect order exists throughout crystalline materials on an atomic
scale. However, such an idealized solid does not exist; all contain large numbers of various defects
or imperfections. As a matter of fact, many of the properties of materials are profoundly sensitive to
deviations from crystalline perfection; the influence is not always adverse, and often specific
characteristics are deliberately fashioned by the introduction of controlled amounts or numbers of
particular defects.

A crystalline defect refers to a lattice irregularity having one or more of its dimensions on the order
of an atomic diameter. Classification of crystalline imperfections is frequently made according to
the geometry or dimensionality of the defect. Several different imperfections, including point
defects (those associated with one or two atomic positions); linear (or one-dimensional) defects;
and interfacial defects, or boundaries, which are two-dimensional. Impurities in solids are also
discussed, because impurity of atoms may exist as point defects.

Let's start with impurities!

A pure metal consisting of only one type of atom just isn't possible; impurity or foreign atoms are
always present, and some exist as crystalline point defects.
It is difficult to refine metals to a purity in excess of 99.9999%. At this level, on the order of 10 22 to
1023 impurity atoms are present in 1 m3 of material.

Alloys

They are not highly pure metal in which impurity atoms have been added intentionally to impart
specific characteristics.

Alloying is used in metals to improve mechanical strength and corrosion resistance.

The addition of impurity atoms to a metal results in the formation of a solid solution and/or a
new second phase.

Solvent is the element or compound that is present in the greatest amount; on occasion,
solvent atoms are also called host atoms.

Solute is used to denote an element or compound present in a minor concentration.

Solid Solutions

A solid solution is compositionally homogeneous; the impurity atoms are randomly and
uniformly dispersed within the solid.

Impurity point defects are found in solid solutions, of which there are two types:

–substitutional (solute or impurity atoms replace or substitute for the host atoms)

–interstitial

Here's a picture of the substitutional and interstitial:
In impurities of solids, there is one rule named Hume-Rothery Rule:

1. Atomic size factor

–Appreciable quantities of a solute may be accommodated in this type of solid solution only when
the difference in atomic radii between the two atom types is less than about 15%. Otherwise, the
solute atoms create substantial lattice distortions and a new phase forms.

2. Crystal Structure

–For appreciable solid solubility, the crystal structures for metals of both atom types must be the
same.

3. Electronegativity factor

–The more electropositive one element and the more electronegative the other, the greater the
likelihood that they will form an intermetallic compound instead of a substitutional solid solution.

4. Valences

–Other factors being equal, a metal has more of a tendency to dissolve another metal of higher
valency than to dissolve one of a lower valency.

3.3 Diffusion Mechanisms
Many reactions and processes that are important in the treatment of materials rely on the transfer
of mass either within a specific solid (ordinarily on a microscopic level) or from a liquid, a gas, or
another solid phase. This is necessarily accomplished by diffusion, the phenomenon of material
transport by atomic motion. This section discusses the atomic mechanisms by which diffusion
occurs, the mathematics of diffusion, and the influence of temperature and diffusing species on
the rate of diffusion.

The phenomenon of diffusion may be demonstrated with the use of a diffusion couple, which is
formed by joining bars of two different metals together so that there is intimate contact between
the two faces.

The phenomenon of material transport by atomic motion. Copper atoms have migrated or diffused
into the nickel, and that nickel has diffused into copper.
 The process by which atoms of one metal diffuse into another is termed interdiffusion,
or impurity diffusion.

–Interdiffusion - there is a net drift or transport of atoms from high- to low-concentration regions.

Diffusion also occurs for pure metals, but all atoms exchanging positions are of the same
type; this is termed self-diffusion.

Two mechanisms for diffusion are possible:

1. Vacancy diffusion - occurs via the exchange of an atom residing on a normal lattice site with an
adjacent vacancy.

2. Interstitial diffusion - an atom migrates from one interstitial position to an empty adjacent one
 In most metal alloys, interstitial diffusion occurs much more rapidly than diffusion by the
vacancy mode, because the interstitial atoms are smaller and thus more mobile.

Furthermore, there are more empty interstitial positions than vacancies; hence, the
probability of interstitial atomic movement is greater than for vacancy diffusion.
Imperfections in Solid
 Crystal Defects
- imperfection in the regular geometrical arrangement of the atoms
in a crystalline solid
- imperfections result from deformation of the solid, rapid cooling
from high temperature, or high-energy radiation (X-rays or
neutrons) striking the solid.
- located at single points, along lines, or on whole surfaces in the
solid
- defects influence its mechanical, electrical, and optical behaviour.
Point defects
are where an
atom is missing
or have an
irregular
position in the
lattice
structure.
Self interstitial – an atom
from the crystal that is
crowded into an interstitial
site, a small void space that
under ordinary
circumstances is not
occupied.
Substitution Impurity – there
is an atom of a different type
than the bulk atoms which
has replaced one of the bulk
atoms in the lattice. They are
usually close in size, about
15% to the bulk atom.
Interstitial Impurity –
atoms are much smaller
than the atoms in the
bulk matrix. It fits into
the open space between
the bulk atoms of the
lattice structure.
Vacancies – one
normally occupied
from which an
atom is missing
Frenkel – a
cation–vacancy and a
cation–interstitial pair.
 Line Defects
Line defects/dislocations atoms are out of position in
the crystal structure. It is generated and move when a
stress is applied.
Edge dislocation is an extra
half plane of atoms “inserted”
into the crystal lattice. Due to
the edge dislocations metals
possess high plasticity
characteristics: ductility and
malleability.
Screw dislocation forms
when one part of crystal
lattice is shifted (through
shear) relative to the
other crystal part. It is
called screw as atomic
planes form a spiral
surface around the
dislocation line.
 Surface Defects
It arise at the boundary between two grains or
small crystals within a larger crystal.
Grain Boundaries – the boundary separating two
small grains or crystals having different
crystallographic orientations in polycrystalline
materials.
Tilt Boundaries – occurs in between of two
slightly misaligned grains that appears as an
array of edge dislocations.
Twin Boundaries – appears as an array of
screw dislocations.
Stacking Faults – formed by fault in the
stacking sequence of atomic planes in
crystals.
 Volume Defects (or Bulk defects)

- It is a three-dimensional aggregates of atoms or
vacancies.
- Much larger defects compared to the previous ones
- Common examples are cracks, pores, and other
phases
 Volume Defects (or Bulk defects)

Inclusions – varies in size from a few microns
to macroscopic dimensions; relatively large,
entered the system as a dirt and usually
formed through precipitation.
 Volume Defects (or Bulk defects)

Voids – holes in the solid formed by
trapped gases or by the accumulation
of vacancies.
 Microscopic Examination
- The grains of many crystals have diameters in order of
micros (10-6 meters)
- Microstructure – Structural features subject to
observation under a microscope
- Microscopy – Use of a microscope in studying crystal
structure
- Photomicrograph – A picture taken by a microscope
Microscopic Techniques
 Optical Microscopy
“Light” microscope

Uses a series of lenses to magnify
images

Has three basic lenses (4x, 10x, and a
third ranging from 20x – 100x)

Has a magnification limit of 2000x
Electron Microscopy

Uses focused beam of electrons to
magnify target

Magnification up to 2,000,000x

Has 4 main types: TEM, SEM, REM,
STEM
 Transmission Electron
Microscopy (TEM)
Original form of electron microscope

Utilizes an electron gun with a tungsten filament

Image projected unto a phosphor viewing screen
 Scanning Electron
Microscopy (SEM)
Scans rectangular area by using a focused beam of electrons

Electrons give off differing energies based on structure of target

Microscope reads these energies and produces a visual
representation
 Reflection Electron
Microscopy (REM)

Like TEM, uses a beam of electrons to develop a
picture of the target

Reads the reflected beam of electrons to form
visual representation
 Scanning Transmission Electron
Microscope (STEM)

A type of Transmission Electron Microscope

Electrons focus on a small area of specimen

Electrons pass through the sample, and a
visual is formed
END
Material Science and
Engineering

Diffusion in Solids
Diffusion Mechanisms
Diffusion is the stepwise migration of
atoms from lattice site to lattice site.

Conditions for the atom to make such
move:
There must be an empty adjacent site.
the atom must have sufficient energy to
break bonds with its neighbor atoms
and then cause some lattice distortion
during the displacement.
 Two Types of Metallic Diffusion

1. Vacancy Diffusion
2. Interstitial Diffusion
 Vacancy Diffusion
Involves the interchange of an atom from a normal lattice position to
an adjacent vacant lattice site or vacancy.
Since diffusing atoms and vacancies exchange positions, the diffusion
of atoms in one direction corresponds to the motion of vacancies in
the opposite direction.
 Interstitial Diffusion

Involves atoms that migrate from an interstitial position to a neighboring one that
is empty.
This mechanism is found for interdiffusion of impurities such as hydrogen, carbon,
nitrogen, and oxygen, which have atoms that are small enough to fit into the
interstitial positions.
In most metal alloys, interstitial diffusion occurs much more rapidly than diffusion
by the vacancy mode, since the interstitial atoms are smaller and thus more
mobile.
 STEADY-STATE DIFFUSION
Diffusion flux does not change in time
 STEADY-STATE DIFFUSION
FICK’S FIRST LAW

where:
Diffusion coefficient or Diffusivity (D) – constant of proportionality
(m2/s)
dC/dx – gradient of concentration
NON STEADY-STATE DIFFUSION
Diffusion flux vary with time
 NON STEADY-STATE DIFFUSION
FICK’S SECOND LAW
- If the diffusion coefficient is independent of
composition (which should be verified for each particular
diffusion situation)
 Factors Affecting Diffusion
Diffusing Species - Self diffusion and interdiffusion are generally
slower than interstitial diffusion.

Diffusion Mechanism - Interstitial is usually faster than vacancy

Microstructure - Diffusion is faster in polycrystalline vs single crystal
materials because of the rapid diffusion along grain boundaries and
dislocation cores.

Temperature - Diffusion is a thermally activated process which occurs
faster at higher temperatures.
END
 Material Science and
Engineering

Electronic Structures and Processes
 CONDUCTORS, SEMICONDUCTORS and INSULATORS

► One way of classifying solid materials is according to the
ease with which they conduct an electric current through
this classification scheme of three groups:
► Conductors
► Semiconductors
► Insulators
A diagram showing the valence and conduction bands of insulators, metals,
and semiconductors. The Fermi level is the name given to the highest energy
occupied electron orbital at absolute zero.
Conductors
In a conductor the valence band is full of electrons,
while the conduction band has some free electrons
and many empty energy levels. The addition of a very
small amount of energy will allow electrons to move
within the conduction band, some rising to a higher
level and others returning to lower levels. This
movement of electrons is electrical conduction.
Semiconductors
In a semiconductor, the gap between the valence
band and conduction band is smaller and at room
temperature there is sufficient energy available to
move some electrons from the valence band into
the conduction band allowing some conduction to
take place. An increase in temperature increases
the conductivity of a semiconductor.
Insulators
In the insulator the valence band is full once again,
but in these substances the energy gap between this
and the empty conduction band is very large. It would
take a great deal of energy to make an electron jump
the gap and to cause the insulator to break down. At
very high temperatures or under very large electric
fields breakdown will occur, and like semiconductors
the greater the temperature the greater the
conduction.
 ELECTRONIC AND IONIC CONDUCTION

An electric current results from the motion of electrically charged
particles in response to forces that act on them from an externally
applied electric field.

Within most solid materials a current arises from the flow of electrons,
which is termed electronic conduction.

For ionic materials a net motion of charged ions is possible that
produces a current, such is termed ionic conduction.
 ENERGY BAND STRUCTURES IN SOLIDS
The electrical properties of a solid material depends upon its electron band
structure – that is, the arrangement of the outermost electron bands and the way
in which they are filled with electrons

Four different types of band structures possible at 0 Kelvin (K):

1. THE FIRST BAND STRUCTURE
❖In this band structure, one outermost band is only partially filled with
electrons. The energy corresponding to the highest filled state at 0 K is
called the Fermi energy (Ef).
❖ This energy band structure is typified by some metals, in particular
those that have a single s valence electrons (e.g. copper).
2. THE SECOND BAND STRUCTURE
❖This structure is also found metals.
❖In this structure, there is an overlap of an empty band and a filled band.
❖Magnesium has this band structure.

3. THE FINAL TWO BAND STRUCTURES
❖ this two band structure are similar.
❖ one band (the valence band) that is completely filled with electrons is separated
from an empty conduction band and an energy gap lies between them.
❖ the difference between the two band structures lies in the magnitude of the
energy gap.
❖for insulators, the band gap is relatively wide while for semiconductors it is
narrow.
❖the Fermi energy for these band structures lies within the band gap near its
center.
Figure 2 The various possible electron band
structures in solids at 0 K
CONDUCTORS
Conductors have vacant energy states adjacent to the
highest filled state at Ef. Thus, very little energy is required
to promote electrons into the low-lying empty states.

Generally, the energy provided by an electric field is
sufficient to excite large numbers of electrons into these
conducting states.
Figure 3 For a metal, occupancy of electron states
(a) before and (b) after an electron excitation.
 Insulators and Semiconductors

For insulators and semiconductors, empty states adjacent to
the top of the filled valence band are not available. To
become free, therefore, electrons must be promoted across
the energy band gap and into empty states at the bottom of
the conduction band.
 Insulators and Semiconductors
The number of electrons excited thermally (by heat energy)
into the conduction band depends on the energy band gap
width as well as temperature. At a given temperature, the
larger the gap the lower is the probability that a valence
electron will be promoted into an energy state within the
conduction band; this results in fewer conduction of
electrons.
 Insulators and Semiconductors

Increasing the temperature of either a semiconductor
or an insulator results in an increase in the thermal
energy that is available for electron excitation. Thus,
more electrons are promoted into the conduction
band, which gives rise to an enhanced conductivity.
Figure 4 For an insulator or semiconductor,
occupancy of electron states (a) before and
(b) after an electron excitation
 ELECTRICAL RESISTIVITY OF METALS
Since crystalline defects serve as scattering centers for conduction
electrons in metals, increasing their number raises the resistivity (or
lowers the conductivity).

Matthiessen’s rule
- the total resistivity of a metal is the sum of the contributions from
thermal vibrations, impurities, and plastic deformation; that is, the
scattering mechanisms act independently of one another.

Which represent the individual thermal, impurity, and deformation
resistivity contributions, respectively.
Table 1 Room-Temperature Electrical
Conductivities for Nine Common Metals and Alloys
 Semiconductivity
The electrical conductivity of the semiconducting materials is
not as high as that of the metals; nevertheless, they have
some unique electrical characteristics that render them
especially useful.

The electrical properties of these materials are extremely
sensitive to the presence of even minute concentrations of
impurities.
 Semiconductivity
Intrinsic semiconductors are those in which the
electrical behavior is based on the electronic structure
inherent in the pure material.

When the electrical characteristics are dictated by
impurity atoms, the semiconductor is said to be
extrinsic.
 INTRINSIC SEMICONDUCTOR
- also called an undoped semiconductor or i-type semiconductor
- a pure semiconductor without any significant dopant species
present.
(dopant is a trace impurity element that is inserted into a
substance to alter the electrical or optical properties of the
substance)

- Pure silicon is therefore an example of an intrinsic semiconductor.
 INTRINSIC SEMICONDUCTOR

Properties:
1. In intrinsic semiconductor, the number density of electrons
is equal to the number density of holes. i.e., ne=nh.
2. The electrical conductivity is low.
3. The electrical conductivity of intrinsic semiconductors
depends on their temperatures
 EXTRINSIC SEMICONDUCTOR

- are semiconductors when a trivalent or pentavalent impurity
is added to a pure semiconductor

- conductivity of extrinsic semiconductor is quite large as
compared to the conductivity of intrinsic semiconductor.
 EXTRINSIC SEMICONDUCTOR

- When some impurity is added in the intrinsic semiconductor,
extrinsic semiconductors can be produced.

- an improved intrinsic semiconductor with a small amount of
impurities added by a process, known as doping, which alters
the electrical properties of the semiconductor and improves its
conductivity.
 EXTRINSIC SEMICONDUCTOR

Properties:
1. In extrinsic semiconductor, the number density of
electrons is not equal to the number density of holes.
2. The electrical conductivity is high.
3. The electrical conductivity depends on the temperature
and the amount of impurity added in them.
END