Madam and Classmate PPTS for Midterms PDF

Summary

These are lecture notes covering material science and engineering, with topics including the introduction to material science, classification of materials, functional classification of materials, and classification of materials based on structure. The class is ENSC 20062. The notes were prepared by Kaycee B. Victorio, likely a professor or teaching assistant at the Polytechnic University of the Philippines in Manila.

Full Transcript

Lecture 2:
Introduction
to Material
Science and
Engineering
ENSC 20062 Material Science and Engineering

Kaycee B. Victorio, REE, RME
Department of Electrical Engineering
College of Engineering
Polytechnic University of the Philippines Manila
 Discussion Outline
 What is Materials Science and
Engineering?
 Classification of Materials
 Functional Classification of Materials
 Classification of Materials Based on
Structure
 Environmental and Other Effects
 Materials Design and Selection
 What is Materials Science and
Engineering?

 Materials Science and Engineering
 Composition means the chemical make-up of a
material.
 Structure means a description of the arrangements
of atoms or ions in a material.
 Synthesis is the process by which materials are
made from naturally occurring or other chemicals.
 Processing means different ways for shaping
materials into useful components or changing their
properties.
© 2003 Brooks/Cole Publishing / Thomson Learning
 © 2003 Brooks/Cole Publishing / Thomson Learning
Application of the tetrahedron of materials science and
engineering to ceramic superconductors. Note that the
microstructure-synthesis and processing-composition are all
interconnected and affect the performance-to-
cost ratio
 © 2003 Brooks/Cole Publishing / Thomson Learning
Application of the tetrahedron of materials science and
engineering to sheet steels for automotive chassis. Note that the
microstructure-synthesis and processing-composition are all
interconnected and affect the performance-to-cost ratio
 © 2003 Brooks/Cole Publishing / Thomson Learning
Application of the tetrahedron of materials science and
engineering to semiconducting polymers for
microelectronics
 Classification of Materials

❑ Metals and Alloys
❑ Ceramics, Glasses,and Glass-ceramics
❑ Polymers (plastics), Thermoplastics and Thermosets
❑ Semiconductors
❑ Composite Materials
 Representative examples,
applications, and properties for each
category of materials

Example of Applications Properties

Metals and Alloys
Gray cast iron Automobile engine blocks Castable, machinable,
vibration damping
Ceramics and
Glasses
SiO2-Na2O-CaO Window glass Optically transparent,
thermally insulating
Polymers
Polyethylene Food packaging Easily formed into thin,
flexible, airtight film
 Representative examples,
applications, and properties for each
category of materials
Example of Applications Properties

Semiconductors
Silicon Transistors and integrated Unique electrical
circuits behavior

Composites Carbide cutting tools for High hardness, yet
Tungsten carbide machining good shock resistance
-cobalt (WC-Co)
 © 2003 Brooks/Cole Publishing / Thomson Learning
Representative strengths of various categories of materials
A section through a jet engine.
The forward compression section
operates at low to medium
temperatures, and titanium parts
are often used. The rear
combustion section operates at A variety of complex ceramic
high temperatures and nickel- components, including
based superalloys are required. impellers and blades, which
The outside shell experiences low allow turbine engines to
temperatures, and aluminum and operate more efficiently at
composites are satisfactory. higher temperatures.
(Courtesy of GE Aircraft (Courtesy of Certech, Inc.)
Engines.)
 © 2003 Brooks/Cole Publishing / Thomson Learning
Polymerization occurs when small molecules, represented by the
circles, combine to produce larger molecules, or polymers. The
polymer molecules can have a structure that consists of many
chains that are entangled but not connected (thermoplastics) or
can form three-dimensional networks in which chains are cross-
linked (thermosets)
 Integrated circuits
for computers and
other electronic
devices rely on the
unique electrical
behavior of
semiconducting
Polymers are used materials. The X-wing for
in a variety of (Courtesy of Rogers advanced helicopters
electronic devices, Corporation.) relies on a material
including these composed of a
computer dip carbon-fiber-
switches, where reinforced polymer.
moisture resistance (Courtesy of Sikorsky
and low Aircraft Division—
conductivity are United Technologies
required. (Courtesy Corporation.)
of CTS Corporation.)
 Functional Classification of
Materials

❑ Aerospace
❑ Biomedical
❑ Electronic Materials
❑ Energy Technology and Environmental Technology
❑ Magnetic Materials
❑ Photonic or Optical Materials
❑ Smart Materials
❑ Structural Materials
© 2003 Brooks/Cole Publishing / Thomson Learning

Functional
classification of
materials.
Notice that
metals, plastics,
and ceramics
occur in
different
categories. A
limited number
of examples in
each category is
provided
Classification of Materials-Based
on Structure

❑ Crystalline material is a material comprised of one or
many crystals. In each crystal, atoms or ions show a
long-range periodic arrangement.
❑ Single crystal is a crystalline material that is made
of only one crystal (there are no grain boundaries).
❑ Grains are the crystals in a polycrystalline material.
❑ Polycrystalline material is a material comprised of
many crystals (as opposed to a single-crystal material
that has only one crystal).
❑ Grain boundaries are regions between grains of a
polycrystalline material.
 Environmental and Other Effects

Effects of following factors must be accounted for in
design to ensure that components do not fail
unexpectedly:

❑ Temperature
❑ Corrosion
❑ Fatigue
❑ Strain Rate
 Increasing
temperature normally
reduces the strength
of a material.
Polymers are suitable
only at low
temperatures. Some
composites, special
alloys, and ceramics,
© 2003 Brooks/Cole Publishing / Thomson Learning

have excellent
properties at high
temperatures
 © 2003 Brooks/Cole Publishing / Thomson Learning
Figure 1.13 Skin operating temperatures for aircraft have
increased with the development of improved materials.
(After M. Steinberg, Scientific American, October, 1986.)
 Materials Design and Selection

❑ Density is mass per unit volume of a material,
usually expressed in units of g/cm3 or lb/in.3
❑ Strength-to-weight ratio is the strength of a material
divided by its density; materials with a high strength-
to-weight ratio are strong but lightweight.
Course Assignment
 Pick a movie you haven’t watched from the The 150 Greatest
Science Fiction Movies of All Time by Rolling Stones
(https://www.rollingstone.com/tv-movies/tv-movie-lists/best-
sci-fi-movies-1234893930/). Watch the movie and take note of
a technology or material that interests you.

Discuss how does material science and engineering plays a role
in the development of technology or material that you find
interesting in the movie. Make an inference what is the
technology or material made of and its structure, and how can
it be process and synthesis. Also, discuss how is the
performance of the technology/material is important and
estimate how much does it cost in Philippine peso.
Course Assignment
 Submission should be made online through our MS Teams in
the Assignments tab. Submission should be in uneditable,
readable, and comment-able format (PDF is recommended!).
 File should be named as follows: CAXX SurnameFNMI (e.g.
CA01 VictorioKCB). Do not forget to write your name, student
number as header in the upper left portion of your submission.
Copying the question/problem will be highly appreciated. DO
NOT FORGET TO HIGLIGHT YOUR FINAL ANSWER. Page
number in the following format Page X of Y (and centered) is
appreciated.
Further Reading
 Ashby, MF, et-al (2013). Materials: Engineering, Science,
Processing and Design (3rd ed). Butterworth-
Heinemann.
 Askeland, DR (2010). The Science and Engineering of
Materials (6th ed). Cengage Learning.
 Askeland, DR (2013). Essentials of Material Science and
Engineering (3rd ed). Cengage Learning.
 Askeland, DR, et-al (2011). The Science and Engineering
of Materials, SI Edition (6th ed). Cengage Learning.
 Callister, WD (2004). Fundamentals of Material Science
and Engineering: An Integrated Approach (2nd ed).
Wiley & Sons.
Further Reading
 Chung, YW (2006). Introduction to Materials Science and
Engineering (1st ed). CRC Press.
 Hashemi, J & Smith, W (2009). Foundations of Material
Science and Engineering (5th ed). McGraw-Hill.
 Newell, JA (2008). Essentials of Modern Material Science
and Engineering (1st ed). Wiley & Sons.
 Shackelford, JF (2008). Introduction to Material Science
for Engineers (7th ed). Prentice Hall.
 Lecture 3: Chemistry of Materials
Structure of Atom
Periodic Table
Next Atomic Bonding
Binding Energy and Interatomic Spacing
Meeting Atomic and Ionic Arrangements
Imperfections
Movements
Lecture 2:
Introduction
to Material
Science and
Engineering
ENSC 20062 Material Science and Engineering

Kaycee B. Victorio, REE, RME
Department of Electrical Engineering
College of Engineering
Polytechnic University of the Philippines Manila
Lecture 3 | Chemistry of Materials
ENSC 20062 Material Science and Engineering
Kaycee B. Victorio, REE, RME
Department of Electrical Engineering | College of Engineering | Polytechnic University of the Philippines Manila

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Discussion Outline
 The Structure of Materials
 The Structure of the Atoms
 The Electron Structure of the Atom
 The Periodic Table
 Atomic Bonding
 Binding Energy and Interatomic Spacing
 Short-Range Order versus Long-Range
Order

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Discussion Outline
 Amorphous Materials: Principles and
Technological Applications
 Lattice, Unit Cells, Basis, and Crystal
Structures
 Allotropic or Polymorphic
Transformations
 Points, Directions, and Planes in the Unit
Cell
 Interstitial Sites
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Discussion Outline
 Crystal Structures of Ionic Materials
 Covalent Structures
 Diffraction Techniques for Crystal
Structure Analysis
 Point Defects
 Other Point Defects
 Dislocations, Observing Dislocations,
and Significance of Dislocations

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Discussion Outline
 Schmid’s Law
 Influence of Crystal Structure
 Surface Defects
 Importance of Defects
 Applications of Diffusion
 Stability of Atoms and Ions
 Mechanisms for Diffusion
 Activation Energy for Diffusion
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Discussion Outline
 Rate of Diffusion (Fick’s First Law)
 Factors Affecting Diffusion
 Permeability of Polymers
 Composition Profile (Fick’s Second Law)
 Diffusion and Materials Processing

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 The Structure of Materials:
Technological Relevance

 Nanotechnology
 Micro-electro-
mechanical (MEMS)
systems-Airbag
sensors
 Nanostructures

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 Table 1 Levels of Structure

Level of Structure Example of Technologies

Atomic Structure Diamond – edge of
cutting tools

Atomic Arrangements: Lead-zirconium-titanate
Long-Range Order [Pb(Zrx Ti1-x )] or PZT –
(LRO) gas igniters

Atomic Arrangements: Amorphous silica - fiber
Short-Range Order optical communications
(SRO) industry

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 Table 1 Levels of Structure
Level of Structure Example of Technologies

Nanostructure Nano-sized particles of
iron oxide – ferrofluids

Microstructure Mechanical strength of
metals and alloys

Macrostructure Paints for automobiles
for corrosion resistance

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 The Structure of the Atom

 The atomic number of an element is equal to the
number of electrons or protons in each atom.
 The atomic mass of an element is equal to the average
number of protons and neutrons in the atom.
 The Avogadro number of an element is the number of
atoms or molecules in a mole.
 The atomic mass unit of an element is the mass of an
atom expressed as 1/12 the mass of a carbon atom.

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 The Electronic Structure of the
Atom
 Quantum numbers are the numbers that assign electrons
in an atom to discrete energy levels.
 A quantum shell is a set of fixed energy levels to which
electrons belong.
 Pauli exclusion principle specifies that no more than two
electrons in a material can have the same energy. The
two electrons have opposite magnetic spins.
 The valence of an atom is the number of electrons in an
atom that participate in bonding or chemical reactions.
 Electronegativity describes the tendency of an atom to
gain an electron.

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 © 2003 Brooks/Cole Publishing / Thomson Learning
The atomic structure of sodium, atomic number 11, showing
the electrons in the K, L, and M quantum shells

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 © 2003 Brooks/Cole Publishing / Thomson Learning
The complete set of quantum numbers for each of the 11
electrons in sodium

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 © 2003 Brooks/Cole Publishing / Thomson Learning
The electronegativities of selected elements relative to the
position of the elements in the periodic table

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 Example 1
Comparing Electronegativities
Using the electronic structures, compare the electronegativities
of calcium and bromine.
SOLUTION
The electronic structures, obtained from Appendix C, are:
Ca: 1s22s22p63s23p6 4s2
Br: 1s22s22p63s23p63d10 4s24p5
Calcium has two electrons in its outer 4s orbital and bromine
has seven electrons in its outer 4s4p orbital. Calcium, with an
electronegativity of 1.0, tends to give up electrons and has low
electronegativity, but bromine, with an electronegativity of 2.8,
tends to accept electrons and is strongly electronegative. This
difference in electronegativity values suggests that these
elements may react readily to form a compound.
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 The Periodic Table

 III-V semiconductor is a semiconductor that is based on
group 3A and 5B elements (e.g. GaAs).
 II-VI semiconductor is a semiconductor that is based on
group 2B and 6B elements (e.g. CdSe).
 Transition elements are the elements whose electronic
configurations are such that their inner “d” and “f” levels
begin to fill up.
 Electropositive element is an element whose atoms want
to participate in chemical interactions by donating
electrons and are therefore highly reactive.

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 18
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The Periodic Table of Elements
© 2003 Brooks/Cole Publishing / Thomson Learning
© 2003 Brooks/Cole Publishing / Thomson Learning
 Atomic Bonding

 Metallic bond, Covalent bond, Ionic bond, van der Waals
bond are the different types of bonds.
 Ductility refers to the ability of materials to be stretched
or bent without breaking
 Van der Waals interactions: London forces, Debye
interaction, Keesom interaction
 Glass temperature is a temperature above which many
polymers and inorganic glasses no longer behave as
brittle materials
 Intermetallic compound is a compound such as Al3V
formed by two or more metallic atoms

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© 2003 Brooks/Cole Publishing / Thomson Learning

The metallic bond
forms when atoms
give up their
valence electrons,
which then form an
electron sea. The
positively charged
atom cores are
bonded by mutual
attraction to the
negatively charged
electrons

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 © 2003 Brooks/Cole Publishing / Thomson Learning
When voltage is applied to a metal, the electrons in the
electron sea can easily move and carry a current
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 © 2003 Brooks/Cole Publishing / Thomson Learning
Covalent bonding requires that electrons be shared between
atoms in such a way that each atom has its outer sp orbital
filled. In silicon, with a valence of four, four covalent bonds
must be formed
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 © 2003 Brooks/Cole Publishing / Thomson Learning
Covalent bonds are directional. In silicon, a tetrahedral
structure is formed, with angles of 109.5° required
between each covalent bond
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 © 2003 Brooks/Cole Publishing / Thomson Learning
The tetrahedral structure of silica (Si02), which contains
covalent bonds between silicon and oxygen atoms

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 Example 2
Design of a Thermistor
A thermistor is a device used to measure temperature by
taking advantage of the change in electrical conductivity
when the temperature changes. Select a material that might
serve as a thermistor in the 500 to 1000oC temperature
range.

Photograph of a commercially
available thermistor. (Courtesy of
Vishay Intertechnology, Inc.)

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Example 2 Design of a Thermistor
The resistance of a thermistor can be made to increase
or decrease with increasing temperature. These are
known as positive temperature coefficient of resistance
(PTCR) or negative temperature coefficient of resistance
(NTCR) thermistors, respectively.The fact that a
thermistor changes its resistance in response to a
temperature change is used to control temperature or
switch (turn ‘‘on’’ and ‘‘off ’’) the operation of an
electrical circuit when a particular device (i.e., a
refrigerator, hairdryer, furnace, oven, or reactor) reaches
a certain temperature.

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Example 2 Design of a Thermistor
Two design requirements must be satisfied. First, a
material with a high melting point must be selected.
Second, the electrical conductivity of the material must
show a systematic and reproducible change as a function
of temperature. Covalently bonded materials might be
suitable. They often have high melting temperatures,
and, as more covalent bonds are broken when the
temperature increases, increasing numbers of electrons
become available to transfer electrical charge.
The semiconductor silicon is one choice: Silicon
melts at 1410oC and is covalently bonded. A number of
ceramic materials also have high melting points and
behave as semiconducting materials. Silicon will have to
be protected against oxidation. We will have to make sure
the changes in conductivity in the temperature range are
actually acceptable. Some thermistors that show a
predictable decrease in the resistance with increasing
temperature are made from semiconducting materials.
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Example 2 Design of a Thermistor
Polymers would not be suitable, even though the
major bonding is covalent, because of their relatively
low melting, or decomposition, temperatures. Many
thermistors that can be used for switching applications
make use of barium titanate (BaTiO3) based
formulations. Many useful NTCR materials are based on
Fe3O4-ZnCr2O4, Fe3O4-MgCr2O4, or Mn3O4, doped with
Ni, Co, or Cu.
In almost any design situation, once the technical
performance criteria are met we should always pay
attention to and take into account the cost of raw
materials, manufacturing costs, and other important
factors such as the durability. In some applications, we
also need to pay closer attention to the environmental
impact including the ability to recycle materials.

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 © 2003 Brooks/Cole Publishing / Thomson Learning

An ionic bond is created between two unlike atoms with
different electronegativities. When sodium donates its valence
electron to chlorine, each becomes an ion; attraction occurs,
and the ionic bond is formed

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 © 2003 Brooks/Cole Publishing / Thomson Learning

When voltage is applied to an ionic material, entire ions must
move to cause a current to flow. Ion movement is slow and the
electrical conductivity is poor
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 © 2003 Brooks/Cole Publishing / Thomson Learning

Illustration of London forces, a type of a van der
Waals force, between atoms

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 © 2003 Brooks/Cole Publishing / Thomson
Learning

The Keesom interactions are formed as a result of polarization
of molecules or groups of atoms. In water, electrons in the
oxygen tend to concentrate away from the hydrogen. The
resulting charge difference permits the molecule to be weakly
bonded to other water molecules

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 (a) In polyvinyl
chloride (PVC), the
chlorine atoms attached
to the polymer chain
have a negative charge
and the hydrogen atoms
are positively charged.
The chains are weakly
bonded by van der
Waals bonds. This
additional bonding
makes PVC stiffer, (b)
When a force is applied
to the polymer, the van
der Waals bonds are
broken and the chains
slide past one another

© 2003 Brooks/Cole Publishing / Thomson
Learning

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 Example 3
Design Strategies for Silica Optical Fibers

Silica is used for making long lengths of optical fibers.
Being a covalently and ionically bonded material, the
strength of Si-O bonds is expected to be high. Other
factors such as susceptibility of silica surfaces to react
with water vapor in atmosphere have a deleterious
effect on the strength of silica fibers. Give n this, what
design strategies can you think of such that silica fibers
could still be bent to a considerable degree without
breaking?

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Example 3 Design Strategies for Silica Optical Fibers
Based on the mixed ionic and covalent bonding in silica
we know that the Si-O bonds are very strong. We also
know that covalent bonds will be directional and hence
we can anticipate silica to exhibit limited ductility.
Therefore, our choices to enhance ductility of optical
fibers are rather limited since the composition is
essentially fixed. Most other glasses are also brittle. We
can make an argument that silica fibers will exhibit
better ductility at higher temperatures. However, we
have to use them for making long lengths of optical
fibers (most of which are to be buried underground or
under the sea) and hence keeping them at an elevated
temperature is not a practical option.

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Example 3 Design Strategies for Silica Optical Fibers
Therefore, we need to understand, beyond what the
nature of bonding consideration can offer us, why glass
fibers exhibit limited ductility. Is this a property that is
intrinsic to the glass or are there external variables that are
causing a change in the chemistry and structure of the
glass? Materials scientists and engineers have recognized
that the lack of ductility in optical glass fibers is linked to
the ability of the silica surface to react with water vapor in
the atmosphere. They have found that water vapor in the
atmosphere reacts with the surface of silica leading to
micro-cracks on the surface.When subjected to stress these
cracks grow rapidly and the fibers break quite easily! They
have also tested silica fibers in a vacuum and found that the
levels to which one can bend fibers are much higher.

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 Binding Energy and Interatomic
Spacing
 Interatomic spacing is the equilibrium spacing between
the centers of two atoms.
 Binding energy is the energy required to separate two
atoms from their equilibrium spacing to an infinite
distance apart.
 Modulus of elasticity is the slope of the stress-strain
curve in the elastic region (E).
 Yield strength is the level of stress above which a
material begins to show permanent deformation.
 Coefficient of thermal expansion (CTE) is the amount by
which a material changes its dimensions when the
temperature changes.

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 Atoms or ions are
separated by and
equilibrium spacing
that corresponds to
the minimum inter-
atomic energy for a
pair of atoms or ions
(or when zero force is
acting to repel or
attract the atoms or
ions)

© 2003 Brooks/Cole Publishing / Thomson
Learning

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 © 2003 Brooks/Cole Publishing / Thomson Learning

The force-distance curve for two materials, showing the
relationship between atomic bonding and the modulus of
elasticity, a steep dFlda slope gives a high modulus

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 © 2003 Brooks/Cole Publishing / Thomson
Learning

The inter-atomic energy (IAE)-separation curve for two
atoms. Materials that display a steep curve with a deep
trough have low linear coefficients of thermal expansion

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 Example 4
Design of a Space Shuttle Arm
NASA’s space shuttles have a long manipulator robot
arm, also known as the Shuttle Remote Manipulator
System or SRMS, that permits astronauts to launch and
retrieve satellites. It is also used to view and monitor the
outside of the space shuttle using a mounted video
camera. Select a suitable material for this device.

NASA’s Shuttle Remote
Manipulator System: SRMS.
Courtesy of Getty Images)

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Example 4 Design of a Space Shuttle Arm
Let’s look at two of the many material choices. First,
the material should be stiff so that little bending
occurs when a load is applied; this feature helps the
operator maneuver the manipulator arm precisely.
Generally, materials with strong bonding and high
melting points also have a high modulus of
elasticity,or stiffness. Second, the material should be
light in weight to permit maximum payloads to be
carried into orbit; a low density is thus desired. It is
estimated that it costs about US $100,000 to take
the weight of a beverage can into space! Thus, the
density must be as low as possible.

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Example 4 Design of a Space Shuttle Arm
Good stiffness is obtained from high-melting-point metals
(such as beryllium and tungsten), from ceramics, and from
certain fibers (such as carbon). Tungsten, however, has a
very high density, while ceramics are very brittle. Beryllium,
which has a modulus of elasticity that is greater than that of
steel and a density that is less than that of aluminum,
might be an excellent candidate. However, toxicity of Be
and its compounds must be considered. The preferred
material is a composite consisting of carbon fibers
embedded in an epoxy matrix. The carbon fibers have an
exceptionally high modulus of elasticity, while the
combination of carbon and epoxy provides a very low-
density material. Other factors such as exposure to low and
high temperatures in space and on earth must also be
considered. The current shuttle robot arm is about 45 feet
long, 15 inches in diameter and weighs about 900 pounds.
When in space it can manipulate weights up to 260 tons.
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 Short-Range Order versus
Long-Range Order

 Short-range order - The regular and predictable
arrangement of the atoms over a short distance - usually
one or two atom spacings.
 Long-range order (LRO) - A regular repetitive
arrangement of atoms in a solid which extends over a
very large distance.
 Bose-Einstein condensate (BEC) - A newly
experimentally verified state of a matter in which a
group of atoms occupy the same quantum ground state.

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 Levels of atomic
arrangements in
materials: (a) Inert
monoatomic gases have
no regular ordering of
atoms: (b,c) Some
materials, including
water vapor, nitrogen
gas, amorphous silicon
and silicate glass have
short-range order. (d)
Metals, alloys, many
ceramics and some
polymers have regular
ordering of atoms/ions
that extends through the
material.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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 Basic Si-0 tetrahedron in
silicate glass.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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 Tetrahedral arrangement of
C-H bonds in polyethylene.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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(a) Photograph of a silicon single
crystal. (b) Micrograph of a
polycrystalline stainless steel showing
grains and grain boundaries
(Courtesy Dr. M. Hua, Dr. I. Garcia,
and Dr. A.J. Deardo.)

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Liquid crystal display. These materials are amorphous in one
state and undergo localized crystallization in response to an
external electric field and are widely used in liquid crystal
displays. (Courtesy of Nick Koudis/PhotoDisc/Getty Images.)

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 (c) 2003 Brooks/Cole Publishing / Thomson
Learning

Classification of materials based on the type of atomic order.

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 Amorphous Materials: Principles
and Technological Applications

 Amorphous materials - Materials, including glasses, that
have no long-range order, or crystal structure.
 Glasses - Solid, non-crystalline materials (typically
derived from the molten state) that have only short-
range atomic order.
 Glass-ceramics - A family of materials typically derived
from molten inorganic glasses and processed into
crystalline materials with very fine grain size and
improved mechanical properties.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

This figure shows a schematic of the blow-stretch process used for
fabrication of a standard two-liter PET (polyethylene terephthalate)
bottle from a preform. The stress induced crystallization leads to
formation of small crystals that help reinforce the remaining
amorphous matrix.

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 (c) 2003 Brooks/Cole Publishing / Thomson
Learning

Atomic arrangements in crystalline silicon and amorphous silicon.
(a) Amorphous silicon. (b) Crystalline silicon. Note the variation in
the inter-atomic distance for amorphous silicon.

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 Lattice, Unit Cells, Basis, and
Crystal Structures

 Lattice - A collection of points that divide space into
smaller equally sized segments.
 Basis - A group of atoms associated with a lattice point.
 Unit cell - A subdivision of the lattice that still retains the
overall characteristics of the entire lattice.
 Atomic radius - The apparent radius of an atom, typically
calculated from the dimensions of the unit cell, using
close-packed directions (depends upon coordination
number).
 Packing factor - The fraction of space in a unit cell
occupied by atoms.

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 The fourteen types
of Bravais lattices
grouped in seven
crystal systems.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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 Definition of the
lattice
parameters and
their use in cubic,
orthorhombic,
and hexagonal
crystal systems.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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 (a) Illustration
showing sharing of
face and corner
atoms. (b) The
models for simple
cubic (SC), body
centered cubic (BCC),
and face-centered
cubic (FCC) unit cells,
assuming only one
atom per lattice point.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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 (c) 2003 Brooks/Cole Publishing / Thomson
Learning

Illustration of coordination in (a) SC and (b) BCC unit cells. Six
atoms touch each atom in SC, while the eight atoms touch each
atom in the BCC unit cell.

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Learning

The hexagonal close-packed (HCP) structure (left) and its unit
cell.

61
62
 Allotropic or Polymorphic
Transformations

 Allotropy - The characteristic of an element being able to
exist in more than one crystal structure, depending on
temperature and pressure.
 Polymorphism - Compounds exhibiting more than one
type of crystal structure.

63
Oxygen gas sensors used in cars and other
applications are based on stabilized zirconia
compositions. (Image courtesy of Bosch ©
Robert Bosch GmbH.)

64
Points, Directions, and Planes in the
Unit Cell

 Miller indices - A shorthand notation to describe certain
crystallographic directions and planes in a material.
Denoted by [ ] brackets. A negative number is
represented by a bar over the number.
 Directions of a form - Crystallographic directions that all
have the same characteristics, although their ‘‘sense’’ is
different. Denoted by h i brackets.
 Repeat distance - The distance from one lattice point to
the adjacent lattice point along a direction.
 Linear density - The number of lattice points per unit
length along a direction.
 Packing fraction - The fraction of a direction (linear-
packing fraction) or a plane (planar-packing factor) that
is actually covered by atoms or ions.

65
Coordinates of selected points in the unit
cell. The number refers to the distance
from the origin in terms of lattice
parameters.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

Equivalency of crystallographic directions of a form in cubic
systems.

67
68
 Determining the
repeat distance,
linear density,
and packing
fraction for
direction in FCC
copper.

(c) 2003 Brooks/Cole Publishing / Thomson Learning

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70
 Miller-Bravais indices are
obtained for crystallographic
planes in HCP unit cells by using
a four-axis coordinate system.

(c) 2003 Brooks/Cole Publishing / Thomson
Learning

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

Typical directions in the HCP unit cell, using both three-and-four-axis
systems. The dashed lines show that the direction is
equivalent to a direction.

72
73
 The ABABAB stacking
sequence of close-
packed planes
produces the HCP
structure.

(c) 2003 Brooks/Cole Publishing / Thomson
Learning

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

The ABCABCABC stacking sequence of close-packed planes
produces the FCC structure.

75
 Interstitial Sites

 Interstitial sites - Locations between the ‘‘normal’’ atoms
or ions in a crystal into which another - usually different
- atom or ion is placed. Typically, the size of this
interstitial location is smaller than the atom or ion that is
to be introduced.
 Cubic site - An interstitial position that has a
coordination number of eight. An atom or ion in the
cubic site touches eight other atoms or ions.
 Octahedral site - An interstitial position that has a
coordination number of six. An atom or ion in the
octahedral site touches six other atoms or ions.
 Tetrahedral site - An interstitial position that has a
coordination number of four. An atom or ion in the
tetrahedral site touches four other atoms or ions.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

The location of the interstitial sites in cubic unit cells. Only representative
sites are shown.

77
78
Crystal Structures of Ionic Materials

 Factors need to be considered in order to understand
crystal structures of ionically bonded solids:
▪ Ionic Radii
▪ Electrical Neutrality
▪ Connection between Anion Polyhedra
▪ Visualization of Crystal Structures Using Computers

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 (c) 2003 Brooks/Cole Publishing / Thomson
Learning

Connection between anion polyhedra. Different possible
connections include sharing of corners, edges, or faces. In this
figure, examples of connections between tetrahedra are shown.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

(a) The cesium chloride structure, a SC unit cell with two ions
(Cs+ and CI-) per lattice point. (b) The sodium chloride structure,
a FCC unit cell with two ions (Na+ + CI-) per lattice point. Note:
Ion sizes not to scale.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning

(a) The zinc blende unit cell, (b) plan view.

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 (c) 2003 Brooks/Cole Publishing / Thomson
Learning

(a) Fluorite unit cell, (b) plan view.

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Learning
(c) 2003 Brooks/Cole Publishing / Thomson

The perovskite unit cell showing the A and B site cations and oxygen
ions occupying the face-center positions of the unit cell. Note: Ions
are not show to scale.

84
Crystal structure of a new high Tc ceramic superconductor
based on a yttrium barium copper oxide. These materials
are unusual in that they are ceramics, yet at low
temperatures their electrical resistance vanishes. (Source:
ill.fr/dif/3D-crystals/superconductor.html; © M. Hewat
1998.)

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Corundum structure of alpha-alumina (α-AI203).

86
 Covalent Structures

 Covalently bonded materials frequently have complex
structures in order to satisfy the directional restraints
imposed by the bonding.
 Diamond cubic (DC) - A special type of face-centered
cubic crystal structure found in carbon, silicon, and other
covalently bonded materials.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning
(a) Tetrahedron and (b) the diamond cubic (DC) unit cell. This
open structure is produced because of the requirements of
covalent bonding.

88
 Learning
(c) 2003 Brooks/Cole Publishing / Thomson
The silicon-oxygen tetrahedron and the resultant β-cristobalite
form of silica.

89
 The unit cell of crystalline polyethylene.

90
(c) 2003 Brooks/Cole Publishing / Thomson Learning
 Diffraction Techniques for Crystal
Structure Analysis

 Diffraction - The constructive interference, or
reinforcement, of a beam of x-rays or electrons
interacting with a material. The diffracted beam provides
useful information concerning the structure of the
material.
 Bragg’s law - The relationship describing the angle at
which a beam of x-rays of a particular wavelength
diffracts from crystallographic planes of a given
interplanar spacing.
 In a diffractometer a moving x-ray detector records the
2y angles at which the beam is diffracted, giving a
characteristic diffraction pattern

91
 (a) Destructive and
(b) reinforcing
interactions between x-
rays and the crystalline
material.
Reinforcement occurs
(c) 2003 Brooks/Cole Publishing / Thomson Learning

at angles that satisfy
Bragg’s law.

92
 Photograph of a XRD
diffractometer. (Courtesy of H&M
Analytical Services.)

93
 (a) Diagram of a
diffractometer, showing
powder sample, incident and
diffracted beams. (b) The
diffraction pattern obtained
from a sample of gold powder.
(c) 2003 Brooks/Cole Publishing / Thomson Learning

94
Photograph of a transmission electron
microscope (TEM) used for analysis of
the microstructure of materials.
(Courtesy of JEOL USA, Inc.)

95
A TEM micrograph of an aluminum alloy (Al-7055)
sample. The diffraction pattern at the right shows large
bright spots that represent diffraction from the main
aluminum matrix grains. The smaller spots originate from
the nano-scale crystals of another compound that is
present in the aluminum alloy. (Courtesy of Dr. JÖrg M.K.
Wiezorek, University of Pittsburgh.)

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 Point Defects

 Point defects - Imperfections, such as vacancies, that are
located typically at one (in some cases a few) sites in the
crystal.
 Extended defects - Defects that involve several
atoms/ions and thus occur over a finite volume of the
crystalline material (e.g., dislocations, stacking faults,
etc.).
 Vacancy - An atom or an ion missing from its regular
crystallographic site.
 Interstitial defect - A point defect produced when an
atom is placed into the crystal at a site that is normally
not a lattice point.
 Substitutional defect - A point defect produced when an
atom is removed from a regular lattice point and replaced
with a different atom, usually of a different size.

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 (c) 2003 Brooks/Cole Publishing / Thomson Learning
Point defects: (a) vacancy, (b) interstitial atom, (c) small
substitutional atom, (d) large substitutional atom, (e) Frenkel defect,
(f) Schottky defect. All of these defects disrupt the perfect
arrangement of the surrounding atoms.
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98
 Other Point Defects

 Interstitialcy - A point defect caused when a ‘‘normal’’
atom occupies an interstitial site in the crystal.
 Frenkel defect - A pair of point defects produced when
an ion moves to create an interstitial site, leaving behind
a vacancy.
 Schottky defect - A point defect in ionically bonded
materials. In order to maintain a neutral charge, a
stoichiometric number of cation and anion vacancies
must form.
 KrÖger-Vink notation - A system used to indicate point
defects in materials. The main body of the notation
indicates the type of defect or the element involved.

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Learning
(c) 2003 Brooks/Cole Publishing / Thomson

When a divalent cation replaces a monovalent cation, a
second monovalent cation must also be removed, creating
a vacancy.

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100
 Dislocations

 Dislocation - A line imperfection in a crystalline material.
 Screw dislocation - A dislocation produced by skewing a
crystal so that one atomic plane produces a spiral ramp
about the dislocation.
 Edge dislocation - A dislocation introduced into the
crystal by adding an ‘‘extra half plane’’ of atoms.
 Mixed dislocation - A dislocation that contains partly
edge components and partly screw components.
 Slip - Deformation of a metallic material by the
movement of dislocations through the crystal.

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101
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The perfect crystal (a) is cut and sheared one atom spacing, (b)
and (c). The line along which shearing occurs is a screw
dislocation. A Burgers vector b is required to close a loop of
equal atom spacings around the screw dislocation.

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102
The perfect crystal in (a) is cut and an extra plane of
atoms is inserted (b). The bottom edge of the extra
plane is an edge dislocation (c). A Burgers vector b is
required to close a loop of equal atom spacings
around the edge dislocation. (Adapted from J.D.
Verhoeven, Fundamentals of Physical Metallurgy,
Wiley, 1975.)

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103
A mixed dislocation. The screw
dislocation at the front face of the
crystal gradually changes to an
edge dislocation at the side of the
crystal. (Adapted from W.T. Read,
Dislocations in Crystals. McGraw-
Hill, 1953.)
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104
Schematic of slip line, slip plane, and slip (Burgers) vector
for (a) an edge dislocation and (b) for a screw dislocation.
(Adapted from J.D. Verhoeven, Fundamentals of Physical
Metallurgy, Wiley, 1975.)

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105
(a) When a shear stress is applied to the dislocation in (a), the atoms
are displaced, causing the dislocation to move one Burgers vector in
the slip direction (b). Continued movement of the dislocation
eventually creates a step (c), and the crystal is deformed. (Adapted
from A.G. Guy, Essentials of Materials Science, McGraw-Hill, 1976.)
(b) Motion of caterpillar is analogous to the motion of a dislocation.
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 107
107
 Observing Dislocations

 Etch pits - Tiny holes created at areas where dislocations
meet the surface. These are used to examine the
presence and number density of dislocations.
 Slip line - A visible line produced at the surface of a
metallic material by the presence of several thousand
dislocations.
 Slip band - Collection of many slip lines, often easily
visible.

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(c) 2003 Brooks/Cole Publishing / Thomson Learning

A sketch illustrating dislocations, slip planes, and etch pit
locations. (Source: Adapted from Physical Metallurgy
Principles, Third Edition, by R.E. Reed-Hill and R.
Abbaschian, p. 92, Figs. 4-7 and 4-8. Copyright (c) 1992
Brooks/Cole Thomson Learning. Adapted by permission.)

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109
Optical image of etch pits in silicon carbide (SiC).
The etch pits correspond to intersection points of
pure edge dislocations with Burgers vector a/3
and the dislocation line 
1 1 20direction along
(perpendicular to the etched surface). Lines of
etch pits represent low angle grain boundaries
(Courtesy of Dr. Marek Skowronski, Carnegie
Mellon University.)
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 Learning
(c) 2003 Brooks/Cole Publishing / Thomson
Learning
(c) 2003 Brooks/Cole Publishing / Thomson

(c)2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license.

Electron photomicrographs of dislocations in Ti3Al: (a)
Dislocation pileups (x26,500). (b) Micrograph at x 100
showing slip lines and grain boundaries in AI. (c) Schematic
of slip bands development.
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 Significance of Dislocations

 Plastic deformation refers to irreversible deformation or
change in shape that occurs when the force or stress
that caused it is removed.
 Elastic deformation - Deformation that is fully recovered
when the stress causing it is removed.
 Dislocation density - The total length of dislocation line
per cubic centimeter in a material.

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 Schmid’s Law

 Schmid’s law -The relationship between shear stress, the
applied stress, and the orientation of the slip system—
that is,  =  cos  cos 
 Critical resolved shear stress - The shear stress required
to cause a dislocation to move and cause slip.

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trademark used herein under license.

(a) A resolved shear stress τ is produced on a slip system.
(Note: (ø + λ) does not have to be 90°.) (b) Movement of
dislocations on the slip system deforms the material. (c)
Resolving the force.

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 Influence of Crystal Structure

 Critical Resolved Shear Stress
 Number of Slip Systems
 Cross-slip - A change in the slip system of a
dislocation.

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 116
116
 Example 5
Ductility of HCP Metal Single Crystals and
Polycrystalline Materials
A single crystal of magnesium (Mg), which has a HCP crystal
structure, can be stretched into a ribbon-like shape four to six
times its original length. However, polycrystalline Mg and other
metals with a HCP structure show limited ductilities. Use the
values of critical resolved shear stress for metals with different
crystal structures and the nature of deformation in
polycrystalline materials to explain this observation.

117
117
 118
118
Example 5 Ductility of HCP Metal Single Crystals and
Polycrystalline Materials

From Table 4-2, we note that for HCP metals such as Mg,
the critical resolved shear stress is low (50–100 psi). We
also note that slip in HCP metals will occur readily on the
basal plane—the primary slip plane. When a single crystal is
deformed, assuming the basal plane is suitably oriented with
applied stress, a very large deformation can occur. This
explains why single crystal Mg can be stretched into a ribbon
four to six times the original size.
When we have a polycrystalline Mg, the deformation
is not as simple. Each crystal must deform such that the
strain developed in any one crystal is accommodated by its
neighbors. In HCP metals, there are no intersecting slip
systems, thus dislocations cannot glide over from one slip
plane in one crystal (grain) onto another slip plane in a
neighboring crystal. As a result, polycrystalline HCP metals
such as Mg show limited ductility.
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 Surface Defects

 Surface defects - Imperfections, such as grain
boundaries, that form a two-dimensional plane within
the crystal.
 Hall-Petch equation - The relationship between yield
strength and grain size in a metallic material—that is,
y =  0 + Kd −1/ 2
 ASTM grain size number (n) - A measure of the size of
the grains in a crystalline material obtained by counting
the number of grains per square inch a magnification 
100.
 Small angle grain boundary - An array of dislocations
causing a small misorientation of the crystal across the
surface of the imperfection.

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(a) The atoms near the boundaries of the
three grains do not have an equilibrium
spacing or arrangement. (b) Grains and
grain boundaries in a stainless steel sample.
(Courtesy Dr. A. Deardo.)

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The effect of grain size on the yield strength of
steel at room temperature.

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122
Microstructure of palladium (x
100). (From ASM Handbook, Vol.
9, Metallography and
Microstructure (1985), ASM
International, Materials Park, OH
44073.)
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123
 The small angle grain boundary
is produced by an array of
dislocations, causing an
angular mismatch θ between
lattices on either side of the
(c) 2003 Brooks/Cole Publishing / Thomson Learning

boundary.

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Application of a stress to the perfect crystal (a) may cause a
displacement of the atoms, (b) causing the formation of a twin.
Note that the crystal has deformed as a result of twinning.
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125
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A micrograph of twins within a grain of brass
(x250).

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126
 127
127
Domains in ferroelectric barium titanate.
(Courtesy of Dr. Rodney Roseman, University of
Cincinnati.) Similar domain structures occur in
ferromagnetic and ferrimagnetic materials.

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128
 Importance of Defects

 Effect on Mechanical Properties via Control of the Slip
Process
 Strain Hardening
 Solid-Solution Strengthening
 Grain-Size Strengthening
 Effects on Electrical, Optical, and Magnetic Properties

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If the dislocation at point A moves to the left, it is
blocked by the point defect. If the dislocation moves to
the right, it interacts with the disturbed lattice near the
second dislocation at point B. If the dislocation moves
farther to the right, it is blocked by a grain boundary.

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 Example 6
Design/Materials Selection for
a Stable Structure
We would like to produce a bracket to hold ceramic bricks
in place in a heat-treating furnace. The bracket should be
strong, should possess some ductility so that it bends
rather than fractures if overloaded, and should maintain
most of its strength up to 600oC. Design the material for
this bracket, considering the various crystal imperfections
as the strengthening mechanism.
SOLUTION
In order to serve up to 600oC, the bracket should not be
produced from a polymer material. Instead, a metal or
ceramic would be considered.

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Example 6 Design/Materials Selection for a Stable
Structure

In order to have some ductility, dislocations must move
and cause slip. Because slip in ceramics is difficult, the
bracket should be produced from a metallic material.

We might add carbon to the iron as interstitial
atoms or substitute vanadium atoms for iron atoms at
normal lattice points. These point defects continue to
interfere with dislocation movement and help to keep the
strength stable.

Of course, other design requirements may be
important as well. For example, the steel bracket may
deteriorate by oxidation or may react with the ceramic
brick.

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Microstructure of iron, for
Problem 4-54 (x500). (From ASM
Handbook, Vol. 9, Metallography
and Microstructure (1985), ASM
International, Materials Park, OH
44073.)

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133
The microstructure of BMT ceramics
obtained by compaction and sintering of
BMT powders. (Courtesy of H. Shirey.)

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 Applications of Diffusion

 Nitriding - Carburization for Surface Hardening of
Steels
 p-n junction - Dopant Diffusion for Semiconductor
Devices
 Manufacturing of Plastic Beverage Bottles/MylarTM
Balloons
 Sputtering, Annealing - Magnetic Materials for Hard
Drives
 Hot dip galvanizing - Coatings and Thin Films
 Thermal Barrier Coatings for Turbine Blades

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Furnace for heat treating steel using
the carburization process. (Courtesy
of Cincinnati Steel Treating).

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 ©2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license.
Schematic of a n-p-n transistor. Diffusion plays a critical role in
formation of the different regions created in the semiconductor
substrates. The creation of millions of such transistors is at the
heart of microelectronics technology

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 Thomson Learning is a trademark used herein under license.
©2003 Brooks/Cole, a division of Thomson Learning, Inc.
Schematic of the
microstructure of the
Co-Pt-Ta-Cr film after
annealing. Most of the
chromium diffuses from
the grains to the grain
boundaries after the
annealing process.
This helps improve the
magnetic properties of Hot dip galvanized parts and structures
the hard disk prevent corrosion. (Courtesy of Casey
Young and Barry Dugan of the Zinc
Corporation of America)
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138
A thermal barrier coating on nickel-based
superalloy. (Courtesy of Dr. F.S. Pettit and Dr.
G.H. Meier, University of Pittsburgh.)

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139
 Stability of Atoms and Ions

 Arrhenius equation
 Activation energy -The energy required to cause a
particular reaction to occur.

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141
reaction
required for a
determine the
can be used to

activation energy

141
in (rate) versus 1/T
The Arrhenius plot of
 Mechanisms for Diffusion

 Self-diffusion - The random movement of atoms
within an essentially pure material.
 Vacancy diffusion - Diffusion of atoms when an
atom leaves a regular lattice position to fill a
vacancy in the crystal.
 Interstitial diffusion - Diffusion of small atoms
from one interstitial position to another in the
crystal structure.

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Diffusion of copper
atoms into nickel.
Eventually, the
copper atoms are
randomly distributed
throughout the nickel

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Diffusion mechanisms in material: (a) vacancy or
substitutional atom diffusion and (b) interstitial diffusion

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 Activation Energy for Diffusion

 Diffusion couple - A combination of elements
involved in diffusion studies
©2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used

A high energy is
required to
squeeze atoms
past one another
herein under license.

during diffusion.
This energy is the
activation energy
Q. Generally more
energy is required
for a substitutional
atom than for an
interstitial atom

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 146
146
 Rate of Diffusion (Fick’s First Law)

 Fick’s first law - The equation relating the flux of
atoms by diffusion to the diffusion coefficient and
the concentration gradient.
 Diffusion coefficient (D) - A temperature-dependent
coefficient related to the rate at which atoms, ions,
or other species diffuse.
 Concentration gradient - The rate of change of
composition with distance in a nonuniform material,
typically expressed as atoms/cm3.cm or at%/cm.

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148
diffusion is

per unit time
defined as the
The flux during

148
number of atoms

plane of unit area
passing through a
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149
gradient
concentration
Illustration of the

149
 Example 7
Semiconductor Doping

One way to manufacture transistors, which amplify
electrical signals, is to diffuse impurity atoms into a
semiconductor material such as silicon (Si). Suppose a
silicon wafer 0.1 cm thick, which originally contains one
phosphorus atom for every 10 million Si atoms, is treated
so that there are 400 phosphorous (P) atoms for every 10
million Si atoms at the surface (Figure 5.16). Calculate the
concentration gradient (a) in atomic percent/cm and (b) in
atoms /cm3.cm. The lattice parameter of silicon is
5.4307 Å.

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license.

Silicon wafer showing variation in concentration
of P atoms (for Example 7)

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Example 7 Semiconductor Doping
a) Calculate the initial and surface compositions in
atomic percent.

1Patom
ci = 7  100 = 0.00001at % P
10 atoms
400 Patom
cs = 7  100 = 0.004at % P
10 atoms
c 0.00001 − 0.004at % P at % P
= = −0.0399
x 0.1cm cm

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Example 7 Semiconductor Doping
b) The volume of the unit cell:
Vcell = (5.4307  10-8 cm)3 = 1.6  10-22 cm3/cell
The volume occupied by 107 Si atoms, which are arranged in a
diamond cubic (DC) structure with 8 atoms/cell, is:
V = 2  10-16 cm3
The compositions in atoms/cm3 are:

1Patom atoms
ci = = 0.005  10 P (
18
−16
)
2  10 cm
3 3
cm
400 Patoms atoms
cs = −16
= 2  1018
P ( )
2  10 cm
3 3
cm
atoms
0.005  10 − 2  10 P (
18 18
)
c cm
3
=
x 0.1cm
atoms
= −1.995  10 P
19

cm3.cm
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 Factors Affecting Diffusion

 Temperature and the Diffusion Coefficient (D)
 Types of Diffusion - volume diffusion, grain
boundary diffusion, Surface diffusion
 Time
 Dependence on Bonding and Crystal Structure
 Dependence on Concentration of Diffusing Species
and Composition of Matrix

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The diffusion
coefficient D as a
function of reciprocal
temperature for some
metals and ceramics.
In the Arrhenius plot,
D represents the rate
of the diffusion
process. A steep
slope denotes a high
activation energy

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 Diffusion coefficients for
different dopants in
silicon. (Source: From
‘‘Diffusion and Diffusion
Induced Defects in
Silicon,’’ by U. GÖsele. In
R. Bloor, M. Flemings, and
S. Mahajan (Eds.),
Encyclopedia of Advanced
Materials, Vol. 1, 1994, p.
631, Fig. 2. Copyright ©
1994 Pergamon Press.
Reprinted with permission
of the authors.)

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Diffusion in ionic compounds. Anions can only enter other
anion sites. Smaller cations tend to diffuse faster

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Diffusion coefficients of ions in different oxides. (Source: Adapted from
Physical Ceramics: Principles for Ceramic Science and Engineering, by Y.M.
Chiang, D. Birnie, and W.D. Kingery, Fig. 3-1. Copyright © 1997 John Wiley
& Sons. Adapted with permission.)
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 159
159
 160
160
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The activation energy for self-diffusion increases as the
melting point of the metal increases
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The dependence of
diffusion coefficient of
Au on concentration.
(Source: Adapted from
Physical Metallurgy
Principles, Third Edition,
by R.E. Reed-Hill and R.
Abbaschian, p. 363, Fig.
12-3. Copyright © 1991
Brooks/Cole Thomson
Learning. Adapted with
permission.)

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 Permeability of Polymers

Permeability is expressed in terms of the volume of gas
or vapor that can permeate per unit area, per unit time,
or per unit thickness at a specified temperature and
relative humidity.

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 Example 8
Design of Carbonated Beverage Bottles
You want to select a polymer for making plastic bottles that
can be used for storing carbonated beverages. What factors
would you consider in choosing a polymer for this
application?

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Example 8 Design of Carbonated Beverage Bottles

 First, since the bottles are to be used for storing
carbonated beverages, a plastic material with a
small diffusivity for carbon dioxide gas should be
chosen.
 The bottles should have enough strength so that
they can survive a fall of about six feet. This is often
tested using a ‘‘drop test.’’
 The surface of the polymer should also be amenable
to printing of labels or other product information.
 The effect of processing on the resultant
microstructure of polymers must also be considered.

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 Composition Profile
(Fick’s Second Law)

 Fick’s second law - The partial differential equation
that describes the rate at which atoms are
redistributed in a material by diffusion.
 Interdiffusion - Diffusion of different atoms in
opposite directions.
 Kirkendall effect - Physical movement of an interface
due to unequal rates of diffusion of the atoms within
the material.
 Purple plague - Formation of voids in gold-aluminum
welds due to unequal rates of diffusion of the two
atoms; eventually failure of the weld can occur.

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Diffusion of atoms into the surface of a material illustrating
the use of Fick’s second law

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second law
error function
Graph showing the

encountered in Fick’s

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argument and value of
 Diffusion and Materials Processing

 Sintering - A high-temperature treatment used to
join small particles.
 Powder metallurgy - A method for producing
monolithic metallic parts.
 Dielectric resonators -Hockey puck-like pieces of
ceramics such as barium magnesium tantalate
(BMT) or barium zinc tantalate (BZN).
 Grain growth - Movement of grain boundaries by
diffusion in order to reduce the amount of grain
boundary area.
 Diffusion bonding - A joining technique in which two
surfaces are pressed together at high pressures and
temperatures.

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Diffusion processes during sintering and powder
metallurgy. Atoms diffuse to points of contact, creating
bridges and reducing the pore size

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Particles of barium magnesium The microstructure of BMT
tantalate (BMT) (Ba(Mg1/3 ceramics obtained by
Ta2/3)O3) powder are shown. This compaction and sintering of
ceramic material is useful in BMT powders. (Courtesy of
making electronic components H. Shirey.)
known as dielectric resonators
that are used for wireless
communications. (Courtesy of H.
Shirey.)

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Grain growth occurs as atoms diffuse across the grain
boundary from one grain to another

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Grain growth in alumina ceramics can be seen from the
SEM micrographs of alumina ceramics. (a) The left
micrograph shows the microstructure of an alumina
ceramic sintered at 1350oC for 150 hours. (b) The right
micrograph shows a sample sintered at 1350oC for 30
hours. (Courtesy of I. Nettleship and R. McAfee.)

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The steps in diffusion bonding: (a) Initially the contact area is
small; (b) application of pressure deforms the surface,
increasing the bonded area; (c) grain boundary diffusion
permits voids to shrink; and (d) final elimination of the voids
requires volume diffusion
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Course Assignment
 For your homework, answer the questions in the Course
Assignment Section.
 Submission should be made online through our MS Teams in
the Assignments tab. Submission should be in uneditable,
readable, and comment-able format (PDF is recommended!).
 File should be named as follows: CAXX SurnameFNMI (e.g.
CA02 VictorioKCB). Do not forget to write your name, student
number as header in the upper left portion of your submission.
Copying the question/problem will be highly appreciated. DO
NOT FORGET TO HIGLIGHT YOUR FINAL ANSWER. Page
number in the following format Page X of Y (and centered) is
appreciated.

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For Further Reading
 Amato, I., Stuff—The Materials The World Is Made Of, Basic
Books, New York, 1997.
 Barrett, Craig R., W. D. Nix, and A. S. Tetelman, The Principles
of Engineering Materials, Prentice-Hall, New York, 1973.
 Jastrzebski, Z., The Nature and Properties of Engineering
Materials, 2nd ed., John Wiley & Sons, New York, 1976.
 Materials Chemistry, L. V. Interrante, L. A. Casper, and A. B.
Ellis, eds., ACS Advances in Chemistry Series, Volume 245,
American Chemical Society, Washington, D.C., 1995.
 Ralls, Kenneth M., T. H. Courtney, and J. Wulff, Introduction to
Materials Science and Engineering, John Wiley & Sons, New
York, 1976.
 Wyckoff, R. W. G., Crystal Structures, 2nd ed., Interscience,
New York, 1963.

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Next Discussion
 Lecture 4 Heat Treatment of Steels and Cast Irons
◼ Designation and Classification of Steels
◼ Simple Heat Treatments
◼ Isothermal Heat Treatments
◼ Quench and Temper Heat Treatments
◼ Effect of Alloying Elements
◼ Application of Hardenability
◼ Specialty Steels
◼ Surface Treatment
◼ Weldability of Steel
◼ Stainless Steels
◼ Cast Irons

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Lecture 3 | Chemistry of Materials
ENSC 20062 Material Science and Engineering
Kaycee B. Victorio, REE, RME
Department of Electrical Engineering | College of Engineering | Polytechnic University of the Philippines Manila

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Lecture 4
FERROUS ALLOYS
ENSC 20062 Material Science and Engineering
Kaycee B. Victorio, REE, RME
Department of Electrical Engineering
College of Engineering
Polytechnic University of the Philippines Manila

1
 Discuss how to use the
eutectoid reaction to
control the structure and
properties of steels
through heat treatment
and alloying.
Discussion
Objectives
Examine two special
classes of ferrous alloys:
stainless steels and cast
irons.

2
Discussion  Designations
and
 Application of
Hardenability
Outline Classification of
 Specialty Steels
Steels
 Simple Heat  Surface
Treatments Treatments
 Isothermal Heat  Weldability of
Treatments Steel
 Quench and  Stainless Stee