The Importance of Engineering Materials in Present World PDF

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This article explores the significance of engineering materials, offering a review of advancements, classifications, properties, and applications. The article discusses the importance of materials science and engineering to various fields, emphasizing the fundamental role of materials in modern technologies and engineering disciplines.

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International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391

The Importance of Engineering Materials in Present
World
Satya Prakash Pandey1, Vishwajeet Singh2
1
Mechanical Engineering Department, Rajarshi Rananjay Sinh Institute of Management and Technology, Amethi (U.P), 227405, India
2
Student of Mechanical Engineering, Rajarshi Rananjay Sinh Institute of Management and Technology, Amethi (U.P), 227405, India

Abstract: Materials had been in use of humanity since time immemorial. Our world is all about materials that are why Materials
Science and Engineering has taken centre-stage position in many developed and developing nations. There have been changes in man’s
choice of materials for his engineering activities. Materials went through ages of man’s activities on earth like the Stone Age, the Iron
Age and the current Silicon age, etc. But the challenges of current worlds needs are constantly fuelling the need discovery and
development of new kinds of materials with the desired properties and the relevant cost to meet the challenges of the world. This
informative article is, therefore, aimed at reviewing the advances made in engineering materials, their classification and the importance
of engineering materials in current day world, their properties and various areas of application.

Keywords: Material, Advancement, Engineering, Importance

1. Introduction From a functional perspective, the role of a materials
scientist is to develop or synthesize new materials, whereas a
Materials are probably more significant in our culture than materials engineer is called upon to create new products or
we realize. Transportation, housing, clothing systems using existing materials and/or to develop
communication, reaction and food production and virtually techniques for processing materials.
every segment of our daily lives is influenced by materials.
Materials have contributed to the advancement of a number 2.1 Elements of Materials Science and Engineering
of technologies, including medicine & health, information &
communication, national security & space, transportation, There are four essential elements in materials science and
structural materials, arts & literature, textiles, personal engineering
hygiene, agriculture & food science & the environment. 1) Processing/synthesis
These inter-disciplinary interactions between the Material 2) Structure/composition
sciences and other fields in the development of new 3) Properties
materials and their applications is to be understood well. 4) Performance/application

As the contribution of materials science and engineering to These four elements of Materials Science and Engineering is
other disciplines increases, it will become necessary for primarily concerned with the study of the basic knowledge
scientists of all backgrounds to better understand it. of materials: the relationships between the
Although it is not feasible for scientists to master a vast composition/structure, properties and processing of
body of scientific knowledge over many disciplines, materials. Materials engineering is mainly concerned with
scientists must gain the skills that will allow them to master the use of this fundamental knowledge to design and to
some specific topics. Our presentation attempts to present a produce materials with properties that will meet the
relatively brief overview of Materials Science and Materials requirements of society. As subjects of study, materials
Engineering and their importance in the present day world. It science and materials engineering are very often closely
will also attempt to examine the four components that make related. The subject ―materials science and engineering"
up the whole gamut of the discipline of materials science combines both a basic knowledge and application and forms
and engineering and their inter-relationship. a bridge between the basic sciences (physics, chemistry and
mathematics) and the various engineering disciplines,
2. Materials Science and Engineering including electrical, mechanical, chemical, and civil and
aerospace engineering.
Materials Science and Engineering – (a) materials science,
(b) materials engineering The structure of a material usually relates to the arrangement
of its internal components. Subatomic structure involves
Materials science involves investigating the relationships electrons within the individual atoms and interactions with
that exist between the structures and properties of materials their nuclei. On an atomic level, structure encompasses the
organization of atoms or molecules relative to one another.
Materials engineering is based on the application of this The next larger structural realm, which contains large groups
structure-property correlations, in designing or engineering of atoms that are normally agglomerated together, is termed
the structure of a material to produce a pre-determined set of ―microscopic, meaning that which is subject to direct
properties observation using some type of microscope. Finally,

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Paper ID: ART20171428 433
 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
structural elements that may be viewed with the naked eye Virtually all important properties of solid materials may be
are termed ―macroscopic. grouped into six different categories:
Material structure can be classified as: macrostructure,
microstructure, substructure, crystal structure, electronic 1) Mechanical properties relate deformation to an applied
structure and nuclear structure. load or force; examples include: elastic modulus or
Young's modulus and strength; tensile and shear
(a) Macro structure - The macrostructure of a material is strengths, hardness, toughness, ductility, deformation and
examined by low-power magnification or naked eye. It fracture behaviours, fatigue and creep strengths, wear
deals with the shape, size and atomic arrangement in a resistance, etc. The important mechanical properties
crystalline material. In case of some crystals, e.g., quartz, affecting the selection of a material are:
external form of the crystal may reflect the internal a) Tensile Strength: This enables the material to resist the
symmetry of atoms. Macrostructure may be observed application of a tensile force. To withstand the tensile
directly on a fracture surface or on a forging specimen. force, the internal structure of the material provides the
The individual crystals of a crystalline material can be internal resistance.
visible, e.g. in a brass doorknob by the constant polishing b) Hardness: It is the degree of resistance to indentation or
and etching action of a human hand and sweat. scratching, abrasion and wear. Alloying techniques and
Macrostructure can reveal flaws, segregations; cracks etc. heat treatment help to achieve the same.
by using proper techniques and one can save much c) Ductility: This is the property of a metal by virtue of
expenses by rejecting defective materials at an early which it can be drawn into wires or elongated before
stage. rupture takes place. It depends upon the grain size of the
(b) Micro structure - This generally refers to the structure metal crystals.
of the material observed under optical microscope. d) Impact Strength: It is the energy required per unit cross-
Optical microscopes can magnify a structure about 1500 sectional area to fracture a specimen, i.e., it is a measure
to 3000 times linear, without loss of resolution of details of the response of a material to shock loading.
of the material structure. We may note that optical e) Wear Resistance: The ability of a material to resist
microscopes can resolve two lines separately when their friction wear under particular conditions, i.e. to maintain
difference of separation is 10–7 m (= 0.1 _m). Cracks, its physical dimensions when in sliding or rolling contact
porosity, non-metallic inclusions within materials can be with a second member.
revealed by examining them under powerful optical f) Corrosion Resistance: Those metals and alloys which
microscope. can withstand the corrosive action of a medium, i.e.
(c) Sub structure - When crystal imperfections such as corrosion processes proceed in them at a relatively low
dislocation in a structure are to be examined, a special rate are termed corrosion-resistant.
microscope having higher magnification and resolution g) Density: This is an important factor of a material where
than the optical microscope is used. Electron microscope weight and thus, the mass is critical, i.e. aircraft
with magnifications 105 are used for this purpose. components.
Another important modern microscope is field ion
microscope, which can produce images of individual 2) Thermal properties of solids can be represented in
atoms as well as defects in atomic arrangements. terms of heat capacity and thermal conductivity; the
(d) Crystal structure - This reveals the atomic arrangement characteristics of a material, which are functions of the
within a crystal. X-ray diffraction techniques and temperature, are termed its thermal properties. One can
electron diffraction method are commonly used for predict the performance of machine components during
studying crystal structure. It is usually sufficient to study normal operation, if he has the knowledge of thermal
the arrangement of atoms within a unit cell. The crystal is properties. Specific heat, latent heat, thermal
formed by a very large number of unit cells forming conductivity, thermal expansion, thermal stresses,
regularly repeating patterns in space. thermal fatigue, etc., are few important thermal
(e) Electronic structure - This refers to the electrons in the properties of materials. These properties play a vital role
outermost shells of individual atoms that form the solid. in selection of material for engineering applications, e.g.
Spectroscopic techniques are commonly used for when materials are considered for high temperature
determining the electronic structure. service. Now, we briefly discuss few of these properties:
(f) Nuclear structure - This is studied by nuclear a) Specific Heat: It is the heat capacity of a unit mass of
spectroscopic techniques, e.g., nuclear magnetic a homogeneous substance. For a homogeneous body,
resonance (NMR) c = C/M, where C is the heat capacity and M is the
mass of the body. One can also define it as the
2.2 Properties of Materials quantity of heat required to raise the temperature of a
unit mass of the substance through 1°C. Its units are
A property is a material trait in terms of the kind and
cal/g/°C.
magnitude of response to a specific imposed stimulus.
b) Thermal Conductivity (K): This represents the
Generally, definitions of properties are made independent of
material shape and size. The properties of engineering amount of heat conducted per unit time through a unit
materials can be classified into two main groups area perpendicular to the direction of heat conduction
(a) physical when the temperature gradient across the heat
(b) Chemical. conducting element is one unit. Truly speaking the
capability of the material to transmit heat through it is

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Paper ID: ART20171428 434
 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
termed as the thermal conductivity. The higher the to their excellent magnetic properties alongwith their high
value of thermal conductivity, the greater is the rate at electrical resistivity these materials today, find use in a
which heat will be transferred through a piece of variety of applications like magnetic recording tapes,
given size. Copper and aluminum are good inductors and transformers, memory elements, microwave
conductors of heat and therefore, extensively used devices, bubble domain devices, recording hard cores, etc.
whenever transfer of heat is desired. Bakelite is a Hysteresis, permeability and coercive forces are some of the
magnetic properties of magnetic substances which are to be
poor conductor of heat and hence used as heat
considered for the manufacture of transformers and other
insulator. The heat flow through an area A which is
electronic components.
perpendicular to the direction of flow is directly
proportional to the area (A) and thermal gradient 4) Electrical Properties- Electrical conductivity,
(dt/dx). resistivity, dielectric strength, the stimulus is an electric
c) Thermal Expansion: All solids expand on heating field are few important electrical properties of a material.
and contract on cooling. Thermal expansion may take A material which offers little resistance to the passage of
place as linear, circumferential or cubical. A solid an electric current is said to be a good conductor of
which expands equally in three mutually orthogonal electricity. The electrical resistance of a material depends
directions is termed as thermally isotropic. The on its dimensions and is given by: Usually resistivity of a
increase in any linear dimension of a solid, e.g. material is quoted in the literature. Unit of resistivity is
length, width, height on heating is termed as linear Ohm-metre. On the basis of electrical resistivity
expansion. The coefficient of linear expansion is the materials are divided as:
a) Conductors
increase in length per unit length per degree rise in
b) Semiconductors
temperature. The increase in volume of a solid on
c) Insulators.
heating is called cubical expansion. The thermal
In general metals are good conductors. Insulators have very
expansion of solids has its origin in the lattice
high resistivity. Ceramic insulators are most common
vibration and lattice vibrations increases with the rise examples and are used on automobile spark plugs, Bakelite
in temperature. Obviously, the thermal conductivity handles for electric iron, plastic coverings on cables in
(K) and electrical conductivity (σ) vary in the same domestic wiring.
fashion from one material to another.
d) Thermal Resistance (RT): It is the resistance offered 5) Optical properties - The optical properties of materials,
by the conductor when heat flow due to temperature e.g. refractive index, reflectivity and absorption
difference between two points of a conductor. It is coefficient etc. affect the light reflection and transmission
given by: where H _ rate of heat flow and ᶿ1 and ᶿ2 the stimulus is electromagnetic or light radiation.
are temperatures at two points (°C).
e) Thermal Diffusivity (h): It is given by: A material 6) Chemical Properties -These properties includes atomic
having high heat requirement per unit volume weight, molecular weight, atomic number, valency,
chemical composition, acidity, alkalinity, etc. These
possesses a low thermal diffusivity because, more
properties govern the selection of materials particularly
heat must be added to or removed from the material
in Chemical plant. Deteriorative characteristics relate to
for effecting a temperature change. the chemical reactivity of materials. In addition to
f) Thermal Fatigue: This is the mechanical effect of structure and properties, two other important components
repeated thermal stresses caused by repeated heating are involved in the science and engineering of
and cooling. The thermal stresses can be very large, materials— namely, ―processing‖ ―performance.With
involving considerable plastic flow. We can see that regard to the relationships of these four components, the
fatigue failures can occur after relatively few cycles. structure of a material will depend on how it is
The effect of the high part of the temperature cycle on processed. Furthermore, a material‗s performance will be
the strength of material plays an important factor in a function of its properties.
reducing its life under thermal fatigue.
3. Classification of Materials in Engineering
3) Magnetic properties demonstrate the response of a
material to the application of a magnetic field. Materials The traditional method is to classify them according to their
in which a state of magnetism can be induced are termed nature into metals, ceramics, polymers and composites. The
magnetic materials. There are five classes into which factors which form the basis of various systems of
magnetic materials may be grouped: classifications of materials in material science and
(i) diamagnetic engineering are:
(ii) paramagnetic 1. The chemical composition of the material,
(iii) ferromagnetic 2. The mode of the occurrence of the material in the nature,
(iv) antiferromagnetic 3. The refining and the manufacturing process to which the
material is subjected to prior to acquiring the required
(v) ferrimagnetic.
properties,
Iron, Cobalt, Nickel and some of their alloys and compounds
4. The atomic and crystalline structure of material and
possess spontaneous magnetisation. Magnetic oxides like
5. The industrial and technical use of the material.
ferrites and garnets could be used at high frequencies. Due

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Paper ID: ART20171428 435
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ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
Common engineering materials that fall within the scope of 3) Ferrous Metals: Iron is the principal constituent of these
material science and engineering may be classified into one ferrous metals. Ferrous alloys contain significant amount
of the following six groups: of non-ferrous metals. Ferrous alloys are extremely
1. Metals (ferrous and non-ferrous) and alloys important for engineering purposes. On the basis of the
2. Ceramics percentage of carbon and their alloying elements present,
3. Organic Polymers these can be classified into following groups:
4. Composites including Wood materials
(a) Mild Steels: The percentage of carbon in these
5. Semi-conductors
materials range from 0.15 % to 0.25 %. These are
6. Biomaterials
7. Advanced Materials moderately strong and have good weldability. The
production cost of these materials is also low.
3.1 Metals and alloys are inorganic materials composed of (b) Medium Carbon Steels: These contains carbon
one or more metallic elements. They may also contain a between 0.3 % to 0.6 %. The strength of these
small number of non-metallic elements. All the elements are materials is high but their weldability is
broadly divided into metals and non-metals according to comparatively less.
their properties. Metals are element substances which readily (c) High Carbon Steels: These contains carbon varying
give up electrons to form metallic bonds and conduct from 0.65 % to 1.5 %. These materials get hard and
electricity. Some of the important basic properties of metals tough by heat treatment and their weldability is poor.
are: The steel formed in which carbon content is up to 1.5
a) Metals are usually good electrical and thermal %, silica up to 0.5%, and manganese up to 1.5 %
conductors,
along with traces of other elements is called plain
b) At ordinary temperature metals are usually solid,
c) To some extent metals are malleable and ductile, carbon steel.
d) The freshly cut surfaces of metals are lustrous, (d) Cast Irons: The carbon content in these substances
e) When struck metal produce typical sound, and vary between 2 % to 4%. The cost of production of
f) Most of the metals form alloys - When two or more pure these substances is quite low and these are used as
metals are melted together to form a new metal whose ferrous casting alloys.
properties are quite different from those of original 4) Non-Ferrous Metals: Out of several non-ferrous metals
metals, it is called an alloy. only seven are available in sufficient quantity reasonably
at low cost and used as common engineering metals.
Metals usually have a crystalline structure and are good These are aluminum, tin, copper, nickel, zinc and
thermal and electrical conductors. Many metals are strong magnesium. Some other non-ferrous metals, about
and ductile at room temperature and maintain good strength fourteen in number, are produced in relatively small
at high and low temperatures. Metallic materials possess
quantities but these are of vital importance in modern
specific properties like plasticity and strength. Few
industry. These include chromium, mercury, cobalt,
favourable characteristics of metallic materials are high
lustre, hardness, resistance to corrosion, good thermal and tungsten, vanadium, molybdenum, antimony, cadmium,
electrical conductivity, malleability, stiffness, the property zirconium, beryllium, niobium, titanium, tantalum and
of magnetism, etc. Metals may be magnetic, non-magnetic manganese.
in nature. 5) Sintered Metals: These materials possess very different
properties and structures as compared to the metals from
These properties of metallic materials are due to: which these substances have been cast. Powder
1) The atoms of which these metallic materials are metallurgy technique is used to produce sintered metals.
composed The metals to be sintered are first obtained in powered
2) The way in which these atoms are arranged in the space form and then mixed in right calculated proportions.
lattice. After mixing properly, they are put in the die of desired
shape and then processed with certain pressure. Finally,
Metallic materials are typically classified according to their one gets them sintered in the furnace.
use in engineering as under: 6) Clad Metals: A sandwich ‗of two materials is prepared
1) Pure Metals: They are obtained by refining the ore. in order to avail the advantage of the properties of both
Mostly, pure metals are not of any use to the engineers. the materials. This technique is termed as cladding.
However, by specialised and very expensive techniques, Using this technique stainless steel is mostly embedded
one can obtain pure metals (purity ~ 99.99 %), e.g. with a thick layer of mild steel, by rolling the two metals
aluminum, copper, etc. together while they are red hot. This technique will not
2) Alloyed Metals: Alloys can be formed by blending two allow corrosion of one surface. Another example of the
or more metals or at least one being metal. The properties use of this technique is cladding of duralumin with thin
of an alloy can be totally different from its constituent sheets of pure aluminum. The surface layers, i.e. outside
substances, e.g. 18-8 stainless steel, which contains 18 layers of aluminum resist corrosion, whereas inner layer
%, chromium and 8 % nickel, in low carbon steel, carbon of duralumin imparts high strength. This technique is
is less than 0.15 % and this is extremely tough, relatively cheap to manufacture.
exceedingly ductile and highly resistant to corrosion.

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Licensed Under Creative Commons Attribution CC BY
Paper ID: ART20171428 436
 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
3.2 Ceramics are inorganic materials consisting of both 4. The Importance of Engineering Materials in
metallic and non-metallic elements bonded together Our Present World
chemically. Ceramics can be crystalline, non-crystalline or a
mixture of both. Generally, they have high melting points Development of new materials has followed a number of
and high chemical stabilities. They also have high hardness different pathways, depending on both the nature of the
and high temperature strength but tend to be brittle. problem being pursued and the means of investigation.
Ceramics are usually poor electrical conductors. Breakthroughs in the discovery of new materials have
ranged from pure serendipity, to trial-and-error approaches,
3.3Polymers are organic materials which consist of long to design by analogy to existing systems. These
molecular chains or networks containing carbon. Most methodologies will remain important in the development of
polymers are non-crystalline, but some consist of mixtures materials but as the challenges and requirements for new
of both crystalline and non-crystalline regions. They materials become more complex, the need to design and
typically have low densities and are mechanically flexible. develop new materials from the molecular scale through the
Their mechanical properties may vary considerably. Most macroscopic final product will become increasingly
polymers are poor electric conductors due to the nature of important. The use of molecular modeling and the
the atomic bonding. engineering of new materials into useable forms or devices
are of particular importance.
3.4 Composites are mixtures of two or more types of
materials. The constituent elements in a composite retain 4.1 Current Trends and Advances in Materials
their identities (they do not dissolve or merge completely
into each other) while acting in concert to provide a host of Timber, steel and cement are the materials which are widely
benefits such as light weight, high strength, corrosion used for engineering applications in huge quantities. The
resistant, high strength-to-weight ratio, directional strength - consumption of steel in any country is considered as an
tailor mechanical properties, high impact strength, high indicator of its economic well being. For high temperature
electric strength (insulator), radar transparent, non-magnetic, applications. Newer materials for combined resistance to
low maintenance, long-term durability, parts consolidation, high temperature and corrosion are increasing rapidly and
dimensional stability, small to large part geometry – material scientists and engineers are busy in developing such
styling/design – sculptural form, customized surface finish, materials. Different kinds of ceramics, though difficult to
rapid installation. Usually, they consist of a matrix phase shape and machine, are finding demand for their use at high
and a reinforcing phase. They are designed to ensure a temperatures. Recently prepared new metallic materials in
combination of the best properties of each of the component conjunction with new processing techniques as isostatic
materials. There is also an increasing trend to classify pressing and isothermal forging are capable of imparting
engineering materials into two further categories: structural better fatigue properties to aircraft components. Powder
materials and functional materials. Structural materials, as metallurgy technique while producing finished surfaces and
the name indicates, are materials used to build structures, cutting down metal cutting cost is much capable of
bodies and components. For instance, in a car the body, imparting improved mechanical properties under different
frame, wheels, seats, inside lining, engine and various loading conditions. Surprisingly, rapid cooling technology
mechanical transmission parts are all constructed from achieving cooling rates in the vicinity of one million degree
structural materials. Celsius per second and this is being used to produce metal
powders which can be used in such product producing
3.5 Semi-ConductorsThese are the materials which have techniques as powder metallurgy and hot isostatic pressing
electrical properties that are intermediate between the to obtain temperature resistant parts. Nowadays,
electrical conductors and insulators. The electrical metallurgists have produced several molybdenum and
characteristics of semi-conductors are extremely sensitive to aluminium alloys as well as alloys of titanium and nickel to
the presence of minute concentrations of impurity atoms; meet anticorrosion properties at elevated temperatures.
these concentrations may be controlled over very small Polymeric materials are growing at annual rate of 9% and
spatial regions. Semi-conductors form the backbone of have grown in volume more than any other material. In
electronic industry. The semi-conductors have made several applications plastics have replaced metals, wood,
possible the advent of integrated circuitrythat has totally glass and paper. A new trend in plastic technology is the
revolutionized the electronics and computer industries. They production of synergistic plastic alloys which have better
affect all walks of life whether it is communications, properties than individual members producing the alloy.
computers, biomedical, power, aviation, defence, Recent discovery of plastic conductors may have wider
entertainment, etc. The field of semi-conductors is rapidly impact in near future. The major drawback of ceramics is the
changing and expected to continue in the next decade. brittleness and difficulty in cutting and shaping. When
Organic semi-conductors are expected to play prominent mixed with metal powder like molybdenum, ceramic
role during this decade. Diamond as semiconductor will also produce cements, which are expected to be useful cutting
be important. Optoelectronic devices will provide three materials. Tool bits of cements are expected to find various
dimensional integration of circuits, and optical computing. applications in attaining high cutting speeds and producing
better surface finish. Alumina, a well-known ceramic is
expected to be successfully reinforced with fibres of
molybdenum. Due to micro cracking of molybdenum fibres,
the attempts to achieve better strength in such composite
ceramics have not been successful yet. However, such
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 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
composites have been found to exhibit better impact and of our lives during this decade with revolution in aviation,
thermal shock resistance. pollution control, and industrial processes.

4.2 Further Advances in Materials Development from 4.5 Nano-Structured Materials and Nanotechnology
View Point of New and Advanced Materials
Nanotechnology is a field that deals with control of
Recent development especially from the point of view of structures and devices at atomic, molecular and super-
new and advanced materials could be classified into: molecular levels as well as the efficient use and manufacture
of these devices. Key areas in Nanotechnology are:
4.3 Advanced Materials 1) Nano-medicine for disease detection and treatment
2) Nano-engineered materials for improved agriculture
The materials that are utilised in high-technology (or high- 3) Nanotechnology for energy
tech) applications are sometimes called advanced materials. 4) Nano porous materials for water filtration
By high technology we mean a device or product that Nanostructured materials are those materials whose
operates or functions using relatively intricate and structural elements clusters, crystallites or molecules have
sophisticated principles; for example, electronic equipment dimensions in the range of 1-100 nm. These small groups of
(VCRs, CD players, etc.), computers, fiber optic systems, atoms, in general, go by different names such as
spacecraft, aircraft and military rocketry. These advanced nanoparticles, nanocrystals, quantum dots and quantum
materials are typically either traditional materials whose boxes. One finds a remarkable variations in fundamental
properties have been enhanced or newly developed high electrical, optical and magnetic properties that occur as one
performance materials. Furthermore, advanced materials progresses from an infinitely extended solid to a particle of
may be of all material types (e.g., metals, ceramics, and material consisting of a countable number of atoms. The
polymers) and are normally relatively expensive. In various types of nanostructured materials which has been
subsequent chapters are discussed the properties and considered for applications in opto-electronic devices and
applications of a good number of advanced materials—for quantum- optic devices are nano-sized powders of silicon,
example, materials that are used for lasers, ICs, magnetic silicon-nitride (SiN), silicon-carbide (SiC) and their thin
information storage, liquid crystal displays (LCDs), fiber films. Some of these are also used as advanced ceramics
optics, and the thermal projection system for the space with controlled micro structures because, their strength and
shuttle orbiter. toughness increase when the grain size diminishes. Carbon-
based nanomaterials and nanostructures including fullerenes
4.4 Smart Materials (Materials of the Future) and nanotube plays an increasingly significant role in
nanoscale science and technology.
Smart or intelligent materials form a group of new materials
now being developed that will have a significant influence
on many of our technologies. In addition, the concept of
smart materials is being extended to rather sophisticated
systems that consist of both smart and traditional materials.
The field of smart materials attempts to combine the sensor,
actuator and the control circuit on as one integrated unit.
Actuators may be called upon to change shape, position,
natural frequency, or mechanical characteristics in response
to changes in temperature, electric fields, and magnetic
fields. The combined system of sensor, actuator and control
circuit on as one IC unit, emulates a biological system.
These are known as smart sensors, microsystem technology Figure 1: nano materials structure
(MST) or microelectromechanical systems (MEMS).
Materials/devices employed as sensors include optical 4.6 Quantom Dots (QDS)
fibers, piezoelectric materials, and MEMS. MEMS devices
are small in size, light weight, low cost, reliable with large Rapid progress in the fabrication of semiconductor
batch fabrication technology. They generally consist of structures has resulted into the reduction of 3D bulk systems
sensors that gather environmental information such as to 2D & 1D, and ultimately to 0D systems. Quantum dots
pressure, temperature, acceleration etc., integrated represent the ultimate reduction in the dimensionality of
electronics to process the data collected and actuators to semiconductor devices. These are 3D semiconductor
influence and control the environment in the desired manner. structures only nanometer in size confining electrons and
The MEMS technology involves a large number of holes. QDs operate at the level of single electron which is
materials. Silicon forms the backbone of these systems also certainly the ultimate limit for an electronic device and are
due to its excellent mechanical properties as well as mature used as the gain material in lasers. QDs are used in quantum
micro-fabrication technology including lithography, etching, dot lasers, QD memory devices, QD photo detectors and
and bonding. Other materials having piezoelectric, even quantum cryptography. The emission wavelength of a
piezoresistive, ferroelectric and other properties are widely quantum dot is a function of its size. So by making dots of
used for sensing and actuating functions in conjunction with different sizes, one can create light of different colors.
silicon. The field of MEMS is expected to touch all aspects

Volume 6 Issue 3, March 2017
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Paper ID: ART20171428 438
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ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391

Figure 3: Spintroniccs

4.8 Fermionic Condensate Matter
Figure 2: Quantum dots representation Very recently scientists had created a new form of matter
called a fermionic condensate matter and predicted it could
4.7 Spintronics lead to the next generation of superconductors. Solids,
liquids, gases, plasma and Bose-Einstein condensate,
A revolutionary new class of semiconductor electronics fermionic condensate matter is a scientific breakthrough in
based on the spin degree of freedom could be created. The providing a new type of quantum mechanical behaviour. It is
study of electron spin in materials is called spintronics. related to Bose-Einstein condensate. However, new state is
Spintronics is based on the direction of spin- and spin- not a superconductor but it is really something in between
coupling. Every appliance ranging from electric bulb to these two states.
laptop computer works on the principle of transport of
electric charge carriers-electrons. The electrons have both
charge and spin. The spin of the electrons could greatly
enhance the particles ‗usefulness. Presently, the
semiconductor technology is based on the number of charges
and their energy. The electron can be assumed as tiny
rotating bar magnet with two possible orientations: spin-up
or spin-down. An applied magnetic field can flip electrons
from one state to another. Obviously, spin can be measured
and manipulated to represent the 0‗s and 1‗s of digital
programming analogous to the ―current on and current off
states in a conventional silicon chip. The performance of
conventional devices is limited in speed and dissipation, Figure 4: Fermionic matter
whereas, spintronic devices are capable of much higher
speed at very low power. Spintronic transistors may work at
5. Breakthroughs in Materials Development
a faster speed, are also smaller in size and will consume less
power. The electron spin may exist not only in the up or
The Material Science has made great strides over the past
down state but also in infinitely many intermediate states
several decades in the development of novel materials.
because of its quantum nature depending on the energy of
Although the following is not meant to be an exhaustive list
the system. This property may lead to highly parallel
of such breakthroughs, these examples point to the range of
computation which could make a quantum computer work
materials and their applications.
much faster for certain types of calculations. The mixed state
could form the base of a computer, built around not only on
Examples such as Teflon serve to show how the chemical
binary bits but the quantum bits or cubit. It is any
sciences have contributed indispensable materials to
combination of a 1 or a 0. Scientists are now trying to use
everyday use. More recently, the development of
the property of the electron-like spin rather than charge to
thermoplastics and structural polymers has had an increasing
develop new generation of microelectronic devices which
influence on applications ranging from construction to
may be more versatile and robust than silicon chips and
national defense. New paints and coatings, clothing fibers,
circuit elements. Spins appear to be remarkably robust and
and photographic films have all benefited from the
move effectively easily between semi-conductors.
development of new materials. There are newer polymeric
materials whose commercial impact has yet to be realized.
Work on semi-conductive and conductive polymers have
made great strides, but further work is necessary. Synthesis
of amphiphilic dendritic block copolymers that are designed
to form ultrathin organic films have also had major
advances, other promising materials, from polymers for drug
delivery to tissue engineering, have the potential to benefit
the biomedical field but are still in a relatively early stage of
development.
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 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
snowmobiles, mobile campers, furniture, microwave
Catalysis Advances in new materials cover a wide range of cookware; Corrosion-Resistant and Chemical-Resistant
applications. Zeolites and pillared clays have had a huge Equipment : tanks, ducts and hoods, pumps, fans, grating,
impact on the petroleum industry. New zeolites with chemical processing, pulp and paper, oil and gas and water /
specified properties continue to be developed with various wastewater treatment markets; Electrical: Components for
utilities. Ziegler-Natta catalysts allow the preparation of both electrical and electronic applications such as pole line
billions of pounds per year of organic polymers with hardware, substation equipment, microwave antennas,
controlled molecular structures and useful material printed wiring boards, etc; Marine: Products for commercial,
properties. This method is also useful because it allows the pleasure and naval boats and ships.
synthesis of polymers that cannot be produced in a practical
manner by any other method. In the energy and 6. Modern Materials Needs & Challenges
transportation sector, catalysis has been an especially fruitful
area of research. As a result, supported gold catalysts have In spite of the tremendous progress made in the field of
been developed. In addition, selective oxidation of carbon material science within the past few years, there still remains
monoxide has been achieved and a gold transition- metal technological challenges, including the development of
oxide has been developed that provides very active NOx more sophisticated and specialized materials, as well as the
reduction as well as hydrocarbon oxidation. The platinum impact of materials production on ecosystem. Nuclear
particles serves to complete the oxidation of hydrocarbons (fission as well as fusion) energy holds some promise, but
and carbon monoxide to carbon dioxide, while rhodium the solutions to the many key problems that remain will,
converts nitrogen oxides to nitrogen and oxygen. The use of necessarily, involve materials from fuels to containment
supramolecular organic templates containing appropriate structures to facilities for the disposal of radioactive waste.
surface functionalities to regulate the nucleation and growth Progress in fusion research has been incredibly rapid in
of inorganic magnets, semiconductors, and catalysts is recent years. There has been major progress in fusion
significant as well. materials and technology, with prototypes of the key
components of a fusion power plant built and successfully
Electronics This broad category has benefited from many tested. Obviously, new high strength, low density structural
breakthroughs in the development of new materials. Perhaps materials remain to be developed, as well as materials that
no recent advance has had a greater impact in this area than have higher temperature capabilities, for use in engine
the creation of chemically amplified photo resist. Photo components. Furthermore, there is an urgent need to find
resist, resins containing photo chemically active polymers, new, economical sources of energy and to make use of
can be coated on a wafer and irradiated using photons present energy resources more economically. Hydrogen
(photolithography), electrons (electron beam lithography), or seems to be the fuel of the future. Hydrogen offers the
X-rays (X-ray lithography). These developments have had greatest potential environment and energy supply benefits.
considerable impact on computer chip production. In the Like electricity, hydrogen is a versatile energy carrier that
field of telecommunications, high-temperature can be made from a variety of widely available primary
superconductors and ceramic materials containing copper- energy sources including natural gas, coal, biomass, wastes,
oxide planes have potential uses in communications sunlight, wind, and nuclear power. Although hydrogen
shielding. The development of new instrumentation is production techniques do exist, further optimization is
essential both in characterizing materials and in exploring desirable for use in energy systems with zero carbon
their potential applications. Matrix-assisted laser desorption emissions. Materials will undoubtedly play a significant role
ionization time-of-flight mass spectrometry (MALDI-TOF), in these developments, We know that environment quality
a mass spectrometry technique that uses laser light to ablate depends on our ability to control air and water pollution.
unfragmented polymer molecules mixed with an organic Pollution control techniques employ various materials.
acid matrix into a time of- flight mass spectrometer, is There is a need to improve material processing and
finding increasing application in the polymer community. refinement methods so that they produce less environmental
degradation. Toxic substances are produced during
Composites – Composites have recently found wide manufacturing processes of some materials and therefore we
application in various area of life such as Aircraft, have to consider the ecological impact of their disposal.
Commercial, pleasure and military aircrafts, including There are many materials which we use are derived from
components for aerospace and related applications; resources that are non renewable, These include polymers
Appliance, Business. Composite applications for the for which the prime raw material is oil, and some metals.
household and office including appliances, power tools, These non renewable resources are gradually becoming
business equipment, etc; Automotive/Transportation :The depleted, which necessitates:
largest of the markets, products include parts for 1) The search of additional reserves
automobiles, trucks, rail and farm applications; Civil 2) The development of new materials having comparable
Infrastructure: A relatively new market for composites, these properties with less adverse environmental impact
applications include the repair and replacement of civil
3) Increased recycling efforts and the development of new
infrastructure including buildings, roads, bridges, piling, etc.
recycling technologies.
Construction: Includes materials for the building of homes,
offices, and architectural components. Products include
swimming pools, bathroom fixtures, wall panels, roofing,
architectural cladding; Consumer products : sports and
recreational equipment such as golf clubs, tennis rackets,
Volume 6 Issue 3, March 2017
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
Paper ID: ART20171428 440
 International Journal of Science and Research (IJSR)
ISSN (Online): 2319-7064
Index Copernicus Value (2015): 78.96 | Impact Factor (2015): 6.391
7. Conclusion Ralls, K. M., T. H. Courtney, and J. Wulff (1976).
Introduction to Materials Science and Engineering, John
Engineering materials always continue to play a significant Wiley & Sons, New York.
role in the current and upcoming future world. The relevant Organising Committee for the Workshop on Materials
factors that will influence this are economic/cost, and Manufacturing, Committee on Challenges for the
environmental requirements, development trends, depletion Chemical Sciences in the 21st Century, National
of traditional materials, advances in research and market Research Council..Materials Science and Technology:
drives, etc. The importance of engineering materials is in Challenges for the Chemical Sciences in the 21st
every aspect of life, therefore, need to be over emphasized. Century by ISBN: 0-309-51684-6, 98 pages, 6 x 9,
We ourselves are materials and so also is everything around (2003) Free PDF downloaded from:
us; to stop talking of and working with materials is to http://www.nap.edu/catalog/10694.html
foreclose the essence of life existence. So a bright future is Schaffer, J. P., A. Saxena, S. D. Antolovich, T. H.
that of even more sophisticated, better and cost effective Sanders, Jr., and S. B. Warner (1999). The Science and
materials. Materials Science, Technology and Engineering Design of Engineering Materials, 2nd edition,
of Materials has the capability of solving problems in WCB/McGraw-Hill, New York.
different sectors of life & the economy. Therefore smart Sigma-Aldrich (2007). ―Advanced Metals and Alloys
nations are quickly creating areas for themselves by Material Matter, Vol. 2, No. 4.
developing materials of both comparative and competitive Smith, W. F. and J. Hashemi (2006). Principles of
advantage as required. Materials Science and Engineering, 4th edition,
McGraw-Hill Book Company, New York..
8. Acknowledgement Van Vlack, L. H. (1989). Elements of Materials Science
and Engineering, 6th edition, Addison-Wesley
We are thankful to our Institute ―R ajarshi Rananjay Sinh Longman, Boston, MA.
Institute of Management & Technology, Amethi ‖for William D. Callister, Jr. (2007). Department of
encouraging us to explore ourselves. The Incubation Centre Metallurgical Engineering, The University of Utah with
of the Institute. Is a beehive of intellectual and innovative special contributions by David G. Rethwisch The
activities? Under the excellent & effective guidance of our University of Iowa - Materials Science and Engineering
faculty from Mechanical Engineering Department, Mr. Satya -An Introduction to Materials Science and
Prakash Pandey Sir, we have completed the informative Engineering.—7th ed.
concepts on materials which focuses on the complete/partial www.wiley.com/college/callister (Student Companion
information of same. Site).
Our Institute has always focused on providing us a
framework for better future for mankind. Also in shaping us Author Profile
to become effective, skilled professionals in coming future. I
Satya Prakash Pandey received the B.Tech. degree in
am very thankful to the Institute‘s Management& our
Mechanical Engineering from IIMT, Meerut in
Director Sir for his influential leadership 2008.He is pursuing M. Tech from KNIT, Sultanpur.
He is now with Rajarshi Rananjay Sinh Institute of
References Management & Technology, Amethi as a Assisstant
Professor in Mechanical Engineering Department.
Ashby, M. F. and D. R. H. Jones(2005). Engineering
Materials 1: An Introduction to Their Properties and Vishwajeet Singh is persuing the B.Tech in
Mechanical Engineering from Rajarshi Rananjay Sinh
Applications, 3rd edition, Butterworth-
Institute of Management & Technology, Amethi.
Heinemann,Woburn, UK. Currently, He is a student of Second Year.
Ashby, M. F. and D. R. H. Jones, Engineering Materials
2: An Introduction to Microstructures, Processing and
Design, 3rd edition, Butterworth- Heinemann,Woburn,
UK, 2005.
Flinn, R. A. and P. K. Trojan (1994). Engineering
Materials and Their Applications, 4th edition, John
Wiley & Sons, New York.
Jacobs, J. A. and T. F. Kilduff (2005). Engineering
Materials Technology, 5th edition, Prentice Hall PTR,
Paramus, NJ.
K. M. Ralls, T. H. Courtney, and J.Wulff, Introduction
to Materials Science and Engineering, p. 22. Copyright
1976 by John Wiley & Sons, New York. Reprinted by
permission of John Wiley & Sons, Inc.)
Murray, G. T. (1993) Introduction to Engineering
Materials— Behavior, Properties, and Selection, Marcel
Dekker, Inc., New York.

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Paper ID: ART20171428 441