EE2EM Engineering Materials Lecture 1 -- Introduction PDF

Summary

This document is a lecture on the introduction to engineering materials. It covers the overview of different types of materials like metals, ceramics, polymers and composites. It describes their properties and applications.

Full Transcript

EE2EM
Engineering Materials
Lecture 1 --Introduction

Dr Mohammed Honnur vali, PhD, CEng, IntePE
Faculty of Engineering and Technology
Muscat University
[email protected]

1
Module Specifications

2
Module Specifications
Why materials?
✓ Please take a few moments and reflect on what your life
would be like without all of the materials that exist in our
modern world.
✓ Believe it or not, without these materials we wouldn’t have
automobiles, cell phones, the internet, airplanes, nice
homes and their furnishings, stylish clothes, nutritious (also
“junk”) food, refrigerators, televisions, computers... (and
the list goes on).
✓ Virtually every segment of our everyday lives is influenced
to one degree or another by materials.
✓ In fact, early civilizations have been designated by the level
of their materials development
✓ 1. Stone Age,
✓ 2. Bronze Age,
✓ 3. Iron Age
----Now?
Silicon Age?
Polymer Age?
Materials discipline
✓ Sometimes it is useful to subdivide the discipline of materials into materials science and materials
engineering subdisciplines.
✓ Materials science involves investigating the relationships that exist between the structures and properties of
materials (i.e., why materials have their properties).
✓ In contrast, 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.
✓ From a functional perspective, the role of a materials scientist is to develop or synthesize new materials.
whereas a materials engineer is called upon to create new products or systems using existing materials
and/or to develop techniques for processing materials.
✓ What is a structure of a material?
In short, structure of a material usually relates to the arrangement of its internal components.

Iron material in raw shape Iron engineered to a specific shape and structure
 Materials discipline
Structural elements may be classified on the basis of size and in
this regard, there are several levels:
Subatomic structure—involves electrons within the individual
atoms, their energies and interactions with the nuclei.
Atomic structure—relates to the organization of atoms to yield
molecules or crystals.
Nanostructure—deals with aggregates of atoms that form
Atomic structure
particles (nanoparticles) that have nanoscale dimensions (less that
about 100 nm).
Microstructure—those structural elements that are subject to
direct observation using some type of microscope (structural
features having dimensions between 100 nm and several
millimeters).
Macrostructure—structural elements that may be viewed with Molecular structure
the naked eye (with scale range between several millimeters and on
the order of a meter).

Macro structure view of iron
Microstructure view of iron Nano structure
 Materials property and their classification
✓ A property is a material trait in terms of the kind and magnitude of response to a
specific imposed stimulus.
✓ Generally, all important properties of solid materials may be grouped into six different
categories: mechanical, electrical, thermal, magnetic, optical, and deteriorative.
✓ Mechanical properties—relate deformation to an applied load or force; examples
include elastic modulus (stiffness), strength, and resistance to fracture.
✓ Electrical properties—the stimulus is an applied electric field; typical properties
include electrical conductivity and dielectric constant.
✓ Thermal properties—are related to changes in temperature or temperature gradients
across a material; examples of thermal behavior include thermal expansion and heat
capacity.

Mechanical properties Electrical properties Thermal properties
 Materials property and their classification
Magnetic properties—the responses of a material to the application
of a magnetic field; common magnetic properties include magnetic
susceptibility and magnetization.
Optical properties—the stimulus is electromagnetic or light radiation;
index of refraction and reflectivity are representative optical
properties.
Deteriorative characteristics—relate to the chemical reactivity of
materials; for example, corrosion resistance of metals.

Magnetic properties Light transmission properties Corrosion of iron
Material Paradigm
✓ In addition to structure and properties, two other important components are involved in the science and
engineering of materials—namely, processing and performance.
✓ With regard to the relationships of these four components, the structure of a material depends on how it is
processed.
✓ Furthermore, a material’s performance is a function of its properties.

Four components of the materials science and Engineering
 Material Paradigm--Example
✓ All these specimens are of the same material, aluminum oxide.
✓ The leftmost one is what we call a single crystal—that is, has a
high degree of perfection—which gives rise to its transparency.
✓ The center one is composed of numerous and very small single
crystals that are all connected; allow the light to scatter lightly,
Which makes the material optically translucent.
✓ Finally, the material on the right consists of many small
interconnected crystals making the crystal appear solid and
scatter the reflected light at a higher rate thus making the
material opaque.
✓ Thus, the structures of these three specimens are different in
terms of crystal boundaries and pores, which affect the optical Example
transmittance properties.
✓ Furthermore, each material was produced using a different
processing technique.
 Case study 1 ✓ During World War II, 2,710 Liberty cargo ships were
mass-produced by the United States to supply food
and materials to the combatants in Europe.
✓ The fracture you are observing is due to brittle
fracture rather ductile.
✓ Some of the ships experienced cracks in their ducks
and hull.
✓ Three of them catastrophically split in half when cracks
formed, grew to critical lengths, and then rapidly
propagated completely around the ships’ girths. (See
the figure)
✓ What did the investigations tell?

1) When some normally ductile metal alloys are cooled to
relatively low temperatures, they become susceptible to
brittle fractures.

The Liberty ship S.S. Schenectady, which, in 1943, failed 2) Welding of the steel frames were done rather than
before leaving the shipyard using riveting method for faster production.
 Case study 1
Remedial measures taken to correct these problems included
the following:
✓Lowering the ductile-to-brittle temperature of the steel to
an acceptable level by improving steel quality (e.g., reducing
sulfur and phosphorus impurity contents)
✓ Installing crack-arresting devices such as riveted straps and
strong weld seams to stop propagating cracks.
✓Improving welding practices and establishing welding code.
 CLASSIFICATION OF MATERIALS
Solid materials have been conveniently grouped into three
basic categories: (based primarily on chemical makeup and
atomic structure)
metals,
ceramics,
and polymers,
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 (e.g.,
iron, aluminium, copper, titanium, gold, nickel), Bar chart of room temperature density values for
various metals, ceramics, polymers, and composite
✓ and often also non-metallic elements (e.g., carbon, nitrogen, materials.
oxygen) 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.
 mechanical characteristics stiff and strength

Familiar objects made of metals and metal alloys (from left to
right): silverware (fork and knife), scissors, coins, a gear, a
wedding ring, and a nut and bolt.

Bar chart of room temperature stiffness (i.e., elastic modulus) values for various
metals, ceramics, polymers, and composite materials.

✓ It can be observed that the metals, ceramics and composites have higher stiffness than the polymers.
 mechanical characteristics stiff and strength

✓ It can be observed that the strength of metal
and composites comparatively have higher
tensile strength than ceramics and polymers.
✓ Metals show high resistance to fracture and
that why is they are widely used in structural
applications.
✓ Similarly, Metallic materials have large
numbers of nonlocalized electrons—that is,
these electrons are not bound to particular
atoms. (free to move)
✓ As a result they are good conductors of
electricity and heat too.
✓ They are not transparent to visible light (i.e. a
polished metal surface has a lustrous
Bar chart of room temperature strength (i.e., tensile strength) values for various appearance).
metals, ceramics, polymers, and composite materials. ✓ In addition, some of the metals (i.e., Fe, Co,
and Ni) have desirable magnetic properties.
 CLASSIFICATION OF MATERIALS
Ceramics
✓ Ceramics are compounds between metallic and non-metallic elements; they
are most frequently oxides, nitrides, and carbides.
✓ For example, common ceramic materials include aluminium oxide (or alumina,
𝐴𝐼2 𝑂3 ), silicon dioxide (or silica, 𝑆𝑖𝑂2 ), silicon carbide (SiC), silicon nitride
(𝑆𝑖3 𝑁4 ).
✓ In addition, what some refer to as the traditional ceramics—those composed of
clay minerals (e.g., porcelain), as well as cement and glass.
✓ With regard to mechanical behavior, ceramic materials are relatively stiff and
strong—stiffnesses and strengths are comparable to those of the metals (see
earlier figures).
✓ In addition, they are typically very hard. Historically, ceramics have exhibited Common objects made of ceramic materials:
extreme brittleness (lack of ductility) and are highly susceptible to fracture scissors, a China teacup, a building brick, a
floor tile, and a glass vase.
✓ However, newer ceramics are being engineered to have improved resistance to
fracture; these materials are used for cookware, cutlery, and even automobile
engine parts. ✓ Regarding optical characteristics,
✓ Furthermore, ceramic materials are typically insulative to the passage of heat ceramics may be transparent,
and electricity (i.e., have low electrical conductivities) and are more resistant to translucent, or opaque, and some
high temperatures and harsh environments than are metals and polymers. of the oxide ceramics (e.g.,
𝐹𝑒3 𝑂4 ) exhibit magnetic
behaviour.
 CLASSIFICATION OF MATERIALS
Polymers
✓ Polymers include the familiar plastic and rubber materials. Many of them
are organic compounds that are chemically based on carbon, hydrogen,
and other non metallic elements (i.e., O, N, and Si).
✓ Some common and familiar polymers are polyethylene (PE), nylon,
poly(vinyl chloride) (PVC), polycarbonate (PC), polystyrene (PS), and
silicone rubber.
✓ These materials typically have low densities, whereas their mechanical
characteristics are generally dissimilar to those of the metallic and ceramic
materials—they are not as stiff or strong as other type materials discussed
earlier.
✓ In addition, many of the polymers are extremely ductile and pliable (i.e.,
plastic), which means they are easily formed into complex shapes.
✓ In general, they are relatively inert chemically and unreactive in a large Several common objects
number of environments. made of polymeric materials: plastic
✓ Furthermore, they have low electrical conductivities and are nonmagnetic. tableware (spoon, fork, and knife), billiard
✓ One major drawback to the polymers is their tendency to soften and/or balls, a bicycle helmet, two dice, a lawn
mower wheel (plastic hub and rubber tire),
decompose at modest temperatures, which, in some instances, limits their and a plastic milk carton.
use.
 CLASSIFICATION OF MATERIALS
Composites
✓ A composite is composed of two (or more) individual materials
that come from the categories previously discussed—metals,
ceramics, and polymers.
✓ 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.
✓ Furthermore, some naturally occurring materials are
composites—for example, wood and bone.
✓ However, most of those we consider in our discussions are
synthetic (or human-made) composites. For examples:
✓ One of the most common and familiar composites is fiberglass, in
which small glass fibers are embedded within a polymeric
material (normally an epoxy or polyester). Fiberglass mat.
 Composites
The glass fibers are relatively strong and stiff (but also
brittle), whereas the polymer is more flexible. Thus,
fiberglass is relatively stiff, strong and flexible. In addition, it
has a low density (which means less weight too).
Another technologically important material is the carbon
fiber–reinforced polymer (CFRP) composite—carbon fibers
that are embedded within a polymer. These materials are
stiffer and stronger than glass fiber–reinforced materials but
more expensive.
Carbon fibre in automobile.
CFRP composites are used in some aircraft and aerospace
applications, as well as in high-tech sporting equipment
(e.g., bicycles, golf clubs, tennis rackets, skis/snowboards)
and recently in automobile bumpers.
 ADVANCED MATERIALS
✓ Materials utilized in high-technology (or high-tech) applications are sometimes termed advanced materials. By high
technology, I mean a device or product that operates or functions using relatively intricate and sophisticated
principles, including electronic equipment (cell phones, DVD players, etc.), computers, fiber-optic systems, high-
energy density batteries, energy-conversion systems, and aircraft.
✓ These advanced materials are typically traditional materials whose properties have been enhanced and also newly
developed, high-performance materials.
Semiconductors
✓ Semiconductors have electrical properties that are
intermediate between those of electrical
conductors (i.e., metals and metal alloys) and
insulators (i.e., ceramics and polymers).
✓ 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. https://youtu.be/c9arR8T0Qts?si=ka9dvhWLFc0gGljv
✓ Semiconductors have made possible the advent of
integrated circuitry that has totally revolutionized
the electronics and computer industries (not to
mention our lives) over the past four decades.
 ADVANCED MATERIALS
Biomaterials

✓ The length and the quality of our lives are being
extended and improved, in part, due to advancements
in the ability to replace diseased and injured body
parts.
✓ Replacement implants are constructed of
biomaterials—nonviable (i.e., non living) materials
that are implanted into the body, so that they function
in a reliable, safe, and physiologically satisfactory
manner, while interacting with living tissue.
✓ That is, biomaterials must be biocompatible—
compatible with body tissues and fluids with which
they are in contact over acceptable time periods.
✓ Example biomaterial applications include joint (e.g.,
hip, knee) and heart valve replacements, vascular
(blood vessel) grafts, fracture-fixation devices, dental
restorations, and generation of new organ tissues.
 ADVANCED MATERIALS
Smart materials
✓ Basically it’s a material that reacts quickly to a stimulus in a specific manner.
✓ The change in the material can also be reversible, as a change in stimulus can bring the material
back to its previous state.
✓ Components of a smart material (or system) include some type of sensor (which detects an input
signal) and an actuator (which performs a responsive and adaptive function).
✓ Actuators may be called upon to change shape, position, natural frequency, or mechanical
characteristics in response to changes in temperature, electric fields, and/or magnetic fields.
✓ Four types of materials are commonly used for actuators: shape-memory alloys, piezoelectric
ceramics, magnetostrictive materials, and electrorheological/magnetorheological fluids.

https://youtu.be/Tn6xKhQ61Vs?si=C_zLvYbLyxde_mBj
Nanomaterials
✓ One new material class that has fascinating properties and tremendous technological promise is the
nanomaterials, which may be any one of the four basic types—metals, ceramics, polymers, or composites.
✓ However, unlike these other materials, they 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).
✓ with the development of scanning probe microscopes, which permit observation of individual atoms and
molecules, it has become possible to design and build new structures from their atomic-level constituents, one
atom or molecule at a time (i.e., “materials by design”).
✓ This ability to arrange atoms carefully provides opportunities to develop mechanical, electrical, magnetic, and
other properties that are not otherwise possible.
✓ We call this the bottom-up approach, and the study of the properties of these materials is termed
nanotechnology.
✓ Some of the physical and chemical characteristics exhibited by matter may experience dramatic changes as
particle size approaches atomic dimensions.
✓ For example, materials that are opaque in the macroscopic domain may become transparent on the nanoscale;
some solids become liquids, chemically stable materials become combustible, and electrical insulators become
conductors.

https://youtu.be/OFV5hqIXSRI?si=qbx0M7MVvHkXnsOw