Nano Materials (Properties and Uses) PDF 2021

Summary

This document is a study on nanomaterials, including their properties and uses. It covers topics such as definitions, history, types, and syntheses. It also discusses various detection techniques and applications.

Full Transcript

The Ministry of Planning
Central Organization for Standardization and Quality Control
Quality Control
Engineering Industries Department

Nanomaterials (Properties and Uses)

Presented By

Dr. Teeb Adnan Mohameed Nihaya Sabry Mutar
( Assistant Chief Engineer) (Engineer)

2021
 List of Contents
No. Subject Page
No.
Chapter One : Introduction of the Nanomaterials
1.1 Definition of Nanomaterials 1
1.2 History of Nanomaterials 1
1.3 Main Differences Between Nanomaterials and Bulk 3
Materials
1.4 Types and Classifications of the Nanomaterials 4
1.4.1 Carbon Nanomaterials 4
1.4.2 Metal and Metal Oxide Nanomaterials 4
1.4.3 Organic Nanomaterials 5
1.4.4 Nanocomposites 5
1.4.5 Ceramic Nanomaterials Nanoceramic 6
1.4.6 Semiconductor Nanomaterials 7
1.4.7 Polymeric Nanomaterials 8
1.5 Classification of Nanomaterials 9
1.5.1 Dimensions and Sizes 9
1.5.2 Origin of Nanomaterials 10
1.5.2.1 Natural Nanomaterials 10
1.5.2.2 Synthetic Nanomaterials 10
Chapter Two : Synthesis of Nanomaterials: Methods & Characterizations
11
2.1 Introduction
2.2 11
Methods to Synthesize Nanomaterials
2.2.1 Production of Nanomaterials by Top-Down Method 12
2.2.2 Production of Nanomaterials by Bottom-Up Method 12
2.2.2.1 Hydrothermal Method 13
2.2.2.2 Solvothermal Method 14
2.2.2.3 Chemical Vapor Deposition Method 14
15
2.2.2.4 Method of Thermal Decomposition and Pulsed Laser
Ablation
2.2.2.5 Templating Method 15
2.2.2.6 Combustion Method 16
2.2.2.7 Gas Phase Method 16
2.2.2.8 Microwave Radiation Method 16
2.2.2.9 Conventional Sol-Gel Method 17
2.3 Characterization of Nanoparticles 17
 2.3.1 Electronic properties 18
2.3.2 Optical properties 18
2.3.3 Magnetic properties 19
2.3.4 Mechanical properties 20
2.3.5 Thermal properties 20
Chapter Three: Methods of detection of Nanomaterials : Techniques and Tool
3.1 Introduction 22
3.2 Scanning Electron Microscopy (SEM) 22
3.3 Transmission Electron Microscopy (TEM) 24
3.4 Fourier Transform Infrared (FTIR) Spectroscopy 27
3.4.1 Main Components of FTIR Instrument 28
3.4.2 Working of FTIR Instrument 28
3.5 X-Ray Diffraction (XRD) 29
3.5.1 Main Components of XRD Instrument 30
3.5.2 Working of XRD Instrument 30
Chapter Four: Applications, Advantages and Disadvantages
Of the Nanomaterials
4.1 Introduction 32
4.2 Electronics 33
4.2.1 Microelectronics 33
4.2.2 Displays 33
4.2.3 Data storage: 33
4.2.4 High energy density batteries 34
4.2.5 High-sensitivity sensors 34
4.3 Transportation and telecommunication 34
4.3.1 Car tires 34
4.3.2 Car bumpers 34
4.4 Imaging 34
4.4.1 Scanning microscope imaging 34
4.4.2 Molecular-recognition AFM tips 34
4.5 Biomedical applications 35
4.5.1 Nanoscaffolds 35
4.5.2 Antimicrobial Nanopowders and Coatings 35
4.5.3 Bioseparation 35
4.5.4 Drug delivery 35
4.5.6 Gene transfection 35

4.5.7 Medical imaging 36
4.5.8 Nasal vaccination 36
4.5.9 Nucleic acid sequence and protein detection 36
4.5.10 Treatment for local anesthetic toxicity 37
4.6 Pollution remediation 37
4.6.1 Elimination of pollutants 37
4.6.2 Water Remediation 38
4.7 Cosmetics 38
4.8 Coatings 38
4.8.1 Self-cleaning windows 38
4.8.2 Scratch resistant materials 38
4.8.3 Textiles 39
4.9 Materials 39
4.9.1 Insulation materials 39
4.9.2 Nanocomposites 39
4.9.3 Paints 39
4.10 Mechanical engineering 39
4.10.1 Cutting tools 39
4.10.2 Lubricants 39
Advantages and Disadvantages of Nanotechnology 40
4.11
4.11.1 Advantages of Nanotechnology 40
4.11.2 Disadvantages of Nanotechnology 41
5.1 Conclusions 42
5.2 Recommendation 42
References 43
 List of Abbreviations
Abbreviate Meaning
NMs Nanomaterials
EN Engineered Nanomaterials
ZnO zinc oxide
Au Gold
Ag Silver
nCHAP Hydroxyapatite Nanoceramics
HAP Hydroxyapatite
NPS Nanoparticles
CVD Chemical Vapor Deposition Method
SiO2 Silicon dioxide
PVD physical vapor deposition
E-beam Electron beam
BT Barium titanate
Al2O3 Aluminum dioxide
Sno2 Tin dioxide
SEM Scanning Electron Microscopy
EDX energy-dispersive X-ray spectroscopy
FTIR Fourier transform infrared spectroscopy
DLS Dynamic light scattering
DFT density functional theory
TGA thermal gravimetric analysis
XRD X-ray diffraction
TEM Transmission electron microscopy
AE Auger electrons
BSE Backscattered electrons
SE Secondary electrons
HR high-resolution
DF Dark-field
BF Dright- field
CNTs Carbone nanotubes
SWCNT2 Single –Walled Carbone nanotubes
AFM Atomic Force Microscopy
Aim of Work
Nanomaterials (nanocrystalline materials) are substances possessing grain
sizes on the order of a billionth of a meter. They manifest extraordinarily
charming and beneficial properties, which can be exploited for a
ramification of structural and nonstructural packages. Seeing that
Nanomaterials own unique, beneficial chemical, bodily, and mechanical
houses, they may be use for an extensive form of programs, like next era
laptop chips, kinetic power (KE) penetrators with more advantageous
lethality, better insulation materials, Phosphors for excessive-Defination
TV, Low cost Flat-Panel displays, more and more difficult cutting tools,
elimination of pollution, excessive strength density, Batteries, excessive
power magnets, high sensitive sensors, motors with greater gas efficiency,
Aerospace addititives with superior performance characteristics, higher
and density weapons platforms, Longer-Lasting Satellites. Longer-Lasting
medical implants, Ductile, Machinable ceramics, huge electro chromic
show devices. Nanotechnology has the potential to be the key to a brand
new world in the field of construction and building materials. Although
replication of natural systems is one of the most promising areas of this
technology, scientists are still trying to grasp their astonishing
complexities. Furthermore, a nanotechnology is a rapidly expanding area
of research where novel properties of materials manufactured on nanoscale
can be utilized for the benefit of construction infrastructure, Therefore, the
main objective of preparing this study is the importance of nanomaterials
and their use in many modern industries due to their mechanical, electrical
and chemical properties and for the purpose of identifying the most
important methods of preparation, detection methods, types and
applications of each type.

I
 Abstract
Nanomaterials (NMs) are gaining significance in technological
applications due to their tunable chemical, physical, and mechanical
properties and enhanced performance when compared with their bulkier
counterparts. This study presents a summary of the general types of NMs
and provides an overview of the various synthesis methods of nanoparticles
(NPs) and their functionalization via covalent or noncovalent interactions
using different methods. It highlights the techniques used for the
characterization of NPs and discusses their physical and chemical
properties. Due to their unique properties, NMs have several applications
and have become part of our daily lives. As a result, research is gaining
attention since some NPs are not easily degraded by the environment.
Thus, this study also highlights research efforts into the fate, behavior, of
different classes of (NMs) in the environment.

II
General Introduction
Nanotechnology is an interdisciplinary study which allows us to develop
new materials with new, interesting and useful properties. These new
materials are nanomaterials made from nanoparticles. Nanoparticles are
ultra-small particles with exceptional properties which can direct
medicines straight to the place where the human body needs them, they can
make materials stronger and they can convert solar energy more efficiently.
Nanoparticles possess different properties and behave differently to the
classical, larger building blocks of substances. From a scientific point of
view, these interesting new properties are not so much the results from the
fact that nanoparticles are small, but they result from the fact that a particle
consisting of a relatively limited number of molecules behaves and
interacts differently with its surroundings for fundamental physical
reasons. Nanoparticles and nanomaterials have gained prominence in
technological advancements due to their adjustable physicochemical
characteristics such as melting point, wettability, electrical and thermal
conductivity, catalytic activity, light absorption and scattering resulting in
enhanced performance over their bulk counterparts. By controlling the
shape, size and internal order of the nanostructures, properties (electrical
conductivity, colour, chemical reactivity, elasticity, etc.) can be modified.

Some nanomaterials occur naturally, but of particular interest are
engineered nanomaterials (EN), which are designed for, and already being
used in many commercial products and processes. They can be found in
such things as sunscreens, cosmetics, sporting goods, stainresistant
clothing, tires, electronics, as well as many other everyday items, and are
used in medicine for purposes of diagnosis, imaging and drug delivery.

III
Engineered nanomaterials are resources designed at the molecular
(nanometre) level to take advantage of their small size and novel properties
which are generally not seen in their conventional, bulk counterparts. The
two main reasons why materials at the nano scale can have different
properties are increased relative surface area and new quantum effects.
Nanomaterials have a much greater surface area to volume ratio than their
conventional forms, which can lead to greater chemical reactivity and
affect their strength. Also at the nano scale, quantum effects can become
much more important in determining the materials properties and
characteristics, leading to novel optical, electrical and magnetic behaviors.

IV
 Chapter One
Introduction of the Nanomaterials
1.1 Definition of Nanomaterials
Nanoscale materials are defined as a set of substances where at least one
dimension is less than approximately 100 nanometers. A nanometer is one
millionth of a millimeter - approximately 100,000 times smaller than the
diameter of a human hair. Nanomaterials are of interest because at this scale
unique optical, magnetic, electrical, and other properties emerge. These
emergent properties have the potential for great impacts in electronics,
medicine, and other fields.

1.2 History of Nanomaterials
Nanotechnology involves the synthesis and application of materials in
dimensions of the order of a billionth of a meter (1x10-9). This categorizes
them under ultrafine particles. (Figure 1.1) reveals the size comparison of the
nanoparticles against different living and nonliving species. The properties
of nanoparticles vary from their bulk counterpart and their chemistry. The
electronic structure, reactivity, and thermal and mechanical properties tend to
change when the particles reach the nanoscale. Through nanotechnology, we
can build materials and devices with control down to the level of individual
atoms and molecules. In the past two decades, there were reports of colloids
and nanoparticles designed by nature [3, 4].

1
Figure (1.1): Size comparison of different structures (living and nonliving).

The history of nanomaterials began immediately after the big bang when
Nanostructures were formed in the early meteorites. Nature later evolved many
other Nanostructures like seashells, skeletons etc. Nanoscaled smoke particles
were formed during the use of fire by early humans. The scientific story of
nanomaterials however began much later. One of the first scientific report is
the colloidal gold particles synthesized by Michael Faraday as early as 1857.
Nanostructured catalysts have also been investigated for over 70 years. By the
early 1940’s, precipitated and fumed silica nanoparticles were being
manufactured and sold in USA and Germany as substitutes for ultrafine carbon
black for rubber reinforcements.

Over the past few years, nanomaterials (NMs) have attracted the
researchers because of their nanosize, physical, biological, and chemical
properties compared to their bulk materials. These NMs are classified based on
their size, chemical composition, shape, and sources. Different types of NMs
have been synthetized from different sources and they are being classified
accordingly. Many NMs have been produced in large quantities based on the
requirements for many industrial applications. The two main sources through
which NMs are being produced are synthetic source and naturally occurring

2
nanoparticles (NPs). In this chapter, we discuss the types and classifications of
NMs and broadly discuss the different types of nanomaterials isolated from
natural and synthetic sources.
1.3 Main differences between nanomaterials and bulk materials
Nanomaterials are particles that have their size in 1-100 nm range at least in
one dimension. We cannot see their particles through the naked eye. Moreover,
examples of these materials include nanozymes, titanium dioxide
nanoparticles, graphene, etc. Bulk materials are particles that have their size
above 100 nm in all dimensions. We can see their particles through the naked
eye. The examples of these materials include plaster, sand, gravel, cement, ore,
slag, salts, etc. The below infographic presents the difference between
nanomaterials and bulk materials in tabular form. Figure (1.2) show the main
different between nanomaterials and bulk materials.

Figure (1.2): General Properties of NMs and Bulk Materials.

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1.4 Types and Classifications of the Nanomaterials
As the field of nanotechnology is growing rapidly, tremendous amount of NMs
have been produced and all these NMs must be identified based on the
structure, shapes, size, and chemical synthesis in order to differentiate from
each other. Interestingly, NMs can be broadly typed into seven categories
which are described below :

1.4.1 Carbon Nanomaterials
The NMs which contain carbon are called carbon nanomaterials, and these
carbon nanomaterials can be synthetized in different shapes such as (1) hollow
tubes or (2) spheres. In addition, carbon nanofibers, graphene, fullerenes,
carbon black, carbon nanotubes, and carbon onions are also classified as
carbon nanomaterials (Figure 1.3).

1.4.2 Metal and Metal Oxide Nanomaterials
The metal and metal oxide can also be used to produce NMs which are called
as metal and metal oxide nanomaterials or inorganic nanomaterials. Some of
these NMs are gold (Au), silver (Ag) nanomaterials and metal oxides-based
nanomaterials are titanium dioxide (TiO2) and zinc oxide (ZnO) nanomaterials.

4
 Figure (1.3) Different Carbon-base nanomaterials.

1.4.3 Organic Nanomaterials
This type of NMs mostly contains organic matter, without carbon or inorganic
based nanomaterials. One of the characteristics of these organic nanomaterials
is that they possess noncovalent bonds (weak in nature, which can be easily
broken). These organic materials can be easily modified to produce different
shapes of nanomaterials like liposomes, dendrimers, micelles, and polymers
(Figure 1.4).

1.4.4 Nanocomposites

The combination of one type of nanomaterials with another type of
nanomaterials is called as nanocomposites. The nanomaterials either combine
with other types of nanowires, nanofibers, or can be combined with larger size
materials. These nanocomposites may be any combinations of metal-based,
carbon-based, or organic- based nanowires, nanofibers, with any form of
ceramic, metal, polymer bulk materials (Figure 1.5).

5
 Figure (1.4): Different types of organic nanomaterials.

Figure (1.5) Structure of nanocomposites.

1.4.5 Ceramic Nanomaterials Nanoceramic
Is a type of NP material composed of ceramics and is further classified as heat-
resistant, inorganic, and nonmetallic solids made of nonmetal and metal
compounds having dimensions smaller than 100 nm. Many chemical and
physical methods for the preparation of ceramic NMs have been explored and
reported. It was found that these materials exhibited enhanced structural,
electro-optical, superconductive, ferromagnetic, and ferroelectric properties.
Similarly, the structural and physical properties of Ti-doped BiFeO3
nanoceramics can be changed by changing the doping concentration, which
could induce the structural distortion of materials and the elimination of

6
oxygen vacancies. Sobierajska et al. reported the preparation of porous
hydroxyapatite nanoceramics and its applications due to its antimicrobial
activity. The calcium hydroxyapatite porous nanoceramics (ncHAP) were
prepared by the co-precipitation of high purity hydroxyapatite (HAP) and
methylcellulose. The specific surface area and the porosity of ncHAP depend
on the sintering temperatures. The interactions between its surface charges and
the bacteria influence its ability in antimicrobial activity. The synthesis of
nanoceramics under pressure-less and low-temperature conditions produce
Al2O3–ZrO2 nanoceramics. The study’s results revealed that amorphous
materials were successfully formed at low temperatures with the homogeneous
mixture and the grain size of NPs.

1.4.6 Semiconductor Nanomaterials
Semiconductor NMs have low bandgap energy of less than 4 eV. Examples of
known semiconductors are silicon, germanium, gallium arsenide, and elements
near the so-called ‘‘metalloid staircase’’ on the periodic table. These NMs are
composed of different compounds from various groups, such as II–VI (ZnO),
IV (SiO2), and III–V (GaAs). The modification of the structure of these
materials into the nanoscale can alter the chemical and physical properties of
the materials due to the quantum size effect or by increasing the surface area.
The C/ZnO semiconductor, with its high porosity, showed that the high
electrical conductivity of the materials depends on the nanostructure formed.
The semiconductor NMs can be divided into two types: (1) intrinsic
semiconductors, composed of pure compounds or elements without doping that
are present from other metals in the structure. The main characteristic of
intrinsic semiconductors is that they have negative temperature coefficients of
resistance. This means that by increasing the temperature, the resistivity of the
material will decrease and the conductivity will increase; (2) extrinsic
semiconductors, which are a type of material added to other metals by doping

7
in its structure, which aims to increase their conductivity, for example, type-n
and type-p semiconductors.

1.4.7 Polymeric nanomaterials

Polymeric NMs are solid particles that are nanosized and consist of natural or
synthetic polymers. These materials are widely used in pharmaceutical and
medical applications as drug release controllers used to sense the body.
Polymer-based NMs include the following: (i) polymeric micelles formed by
the self-assembly of amphiphilic block copolymers in a specified solvent.
Chitosan polymeric micelles can be used for drug delivery due to their unique
characteristics, such as their nanosize, stability, biocompatibility, micellar
association, and low toxicity ; (ii) polymeric NPs, which are generally
composed of biocompatible and biodegradable polymers with an average size
of 10–1000 nm. These materials are widely used to deliver drugs to specific
targets. The preparation methods to produce polymer NPs affect the
specific characteristics of the material produced. Generally, the
preparation methods are classified as polymerization of monomers, the ionic
gelation of hydrophilic polymers, and the dispersion of polymers; (iii)
dendrimers, which have a size of less than 15 nm with 3D-shaped
macromolecules. These materials are a new type of polymeric NMs that are
widely used in pharmaceutical and medical applications due to characteristics
such as their structure, size, and multivalence ; and (iv) polymeric
nanocomposites, which are a combination of other nanofillers and polymers
used to provide superior properties and characteristics.

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1.5 Classification of Nanomaterials
1.5.1 Dimensions and Sizes
As different types of nanomaterials are produced for a variety of applications,
it becomes necessary to categorize these nanomaterials for proper applications.
The nanomaterials are mostly solid particles, and their size and dimensions can
be easily measured by using different methods. The idea for classification of
nanomaterials was proposed by a scientist in the year 2000 , he classified the
nanomaterials based on their crystalline forms and chemical compositions.
Still, this method of measuring was not fully complete as it did not measure
dimensions of the nanomaterials. In another study, different groups of
researchers have made a new classification which was primarily based on 0
Dimension, 1 Dimension, 2 Dimension, and 3 Dimension nanomaterial.
The classification of nanomaterial is basically dependent on the movement of
electrons in the nanomaterial. The presence of electrons is generally fixed in
“0” dimension nanomaterials, whereas for “1” dimension nanomaterials,
electrons can move freely along the x-axis, which is commonly less than
100 nm. Similarly, “2” dimension and “3” dimension nanomaterials have better
electron movements along the x- to y-axis or x-, y-, z-axis, respectively. It has
been found that the ability to predict the properties of nanomaterials determines
the classification of the nanomaterials. Moreover, the characteristics of
nanomaterials are basically dependent on the grain boundaries as per the
Gleiter’s classification, whereas the classification by Pokropivny and
Skorokhod suggested that the characteristics of nanomaterials are ascribed to
the nanoparticle shapes and dimensionalities.

9
1.5.2 Origin of Nanomaterials
The nanomaterials can be classified based on their source of origin, which
means, the source materials to produce nanomaterials. They can be classified
as naturally origin nanomaterials or synthetically produced nanomaterials.

1.5.2.1 Natural Nanomaterials
Natural nanomaterials can be formed in biological species such as microbes, or
plants and also through anthropogenic actions. The creation of natural
nanomaterials is an accessible process as they are present in the hydrosphere,
atmosphere, lithosphere, and biosphere. Interestingly, our planet is comprised
of nanomaterials that are naturally formed and are present in the rivers,
groundwater oceans, lakes, rocks, soils, magma, or lava as well as in the
microbial organisms and also in humans [20, 21]

1.5.2.2 Synthetic Nanomaterials
The most widely used method to make nanomaterials is the synthetic method,
which allows the production of nanomaterials by biological, physical,
chemical, or hybrid methods. One of the advantages of the synthetically
produced nanomaterials is that it is possible to produce large quantity of
nanomaterials with different shapes and sizes. Another important aspect of the
synthetic method is that different chemicals or reagents can be linked or
conjugated with nanomaterials accurately and precisely. The major concern
among synthetically designed nanomaterials is whether present knowledge is
sufficient to envisage their performance. In addition, they display a different
environment behavior, which is different from natural nanomaterials.
Presently, diverse sources of nanomaterials are produced for various biological
applications.

10
 Chapter Two
Synthesis of Nanomaterials: Methods & Characterizations
2.1 Introduction
Over the past couple of decades, various methods of preparation and
synthesis of nanomaterials have been developed. The main objectives of
the synthesis of nanomaterials are to ensure that for what purpose these
nanomaterials are being synthesized. The researchers should know the
applications of the nanomaterials so that they can synthesize
them accordingly. The method of production of nanomaterials to be used
in the industrial application for the development of various products will
be different than the method of production to be used in biological or
medical applications. Other objectives of the researchers to synthetize
nanomaterials are better functionality and lower cost. Over the past few
years, several physical and chemical methods have been used to improve
the performance of nanomaterials demonstrating enhanced properties.

2.2 Methods to Synthesize Nanomaterials
The “top-down” and “bottom-up” are the two major methods which have
been used to successfully synthesize nanomaterials. We have described
these methods in further detail (Figure 2.1).

11
 Figure (2.1) Diagrammatic representation of top-down approach and
bottom-down approach of making of nanomaterials.

2.2.1 Production of Nanomaterials by Top-Down Method
In this method, solid and state processing of the materials are mostly used
and this method involves breaking of the bulk material into smaller
particles using physical processes such as crushing, milling, and grinding
methods. Generally, this method is not appropriate for formulating evenly
shaped nanomaterials, and it is very difficult to get very small size
nanoparticles even with high energy usages. The major difficulty of this
method is the shortage of the surface structure as it has significant impact
on physical properties and surface chemistry of nanomaterials. In
addition, this method also causes substantial crystallographic loss to the
processed shapes.
2.2.2 Production of Nanomaterials by Bottom-Up Method
In this method, materials are prepared by atom-by-atom or molecule-by-
molecule to make large amount of materials. This method is more
frequently used for producing most of the nanomaterials. This method has
an ability to produce a uniform size, shape, and well- distributed
nanomaterials. It basically control the chemical synthesis process in a

12
precisely manner to prevent undesirable particle growth. This method
plays an important role in the production and processing of nanomaterials
with better particle size distribution and better morphology. Another
important feature is that its an environment friendly and economical
processes for the nanoparticle production. There are many
approaches for synthesizing nanomaterials like hydrothermal, combustion
synthesis, gas-phase methods, microwave synthesis, and sol-gel
processing , which we have described below.

2.2.2.1 Hydrothermal Method
The hydrothermal method is normally done in a pressurized container
which is called as an “Autoclave” where temperature and pressure can be
controlled and regulated. During nanomaterial synthesis, the temperature
can be increased at the boiling point of water, which allows the vapor to
get saturated. This method (Figure 2.2) has been extensively used in the
production of different nanoparticles. The advantage of this method
is that this can be useful to control material size, particle morphology,
crystalline phase, and surface chemistry through regulation of the reaction
temperature, pressure, solvent properties, solution composition, and
additives.

Figure (2.2) Diagrammatic representation of hydrothermal process
nanoparticle production.

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2.2.2.2 Solvothermal Method
The solvothermal method (Figur 2.3) is like hydrothermal method, the
only difference is that it uses different solvents other than water.
Interestingly, this method is more effective in synthesis of nanomaterials
with good distribution, especially when organic solvents or chemicals
with high boiling points are selected. Moreover, this method provides
better controlling method to produce better size and shapes of the
materials than the hydrothermal method. This method synthetizes
nanomaterials or nanorods with or without the addition of surfactants.

Figure (2.3) Diagrammatic representation of solvothermal process of
nanoparticle production.

2.2.2.3 Chemical Vapor Deposition Method
The chemical vapor deposition (CVD) method is used to manufacture
high performance thin nano-films. In this method, substrate is basically
treated with volatile precursors which act on the substrate surface to
produce the desirable films. Usually, volatile by-products are eliminated
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by gas flow through the reaction chamber. The quality of the deposited
materials on the surface is greatly dependent on several factors like
temperature, rate of reaction, and the amount of the precursors. It has
been reported that Sn4+doped TiO2 nanoparticle films were produced by
CVD method. Another doped TiO2 nanoparticle was synthesized by
CVD method where TiO2 is crystallized into the rutile structures
depending on the type and number of cations present in the chemical
reactions. The advantage of this method is getting consistent glaze of the
nano film, but this method has many limitations including higher
temperatures required for chemical reactions, and secondly it is difficult
to scale up.

2.2.2.4 Method of Thermal Decomposition and Pulsed Laser Ablation
The doped metals can be produced by using decomposing metal
alkoxides, salts, heat or electricity. Moreover, the properties of
nanomaterials strongly depend on the flow rate of the precursor’s
concentrations in the reactions and its environment. It has been reported
that TiO2 nanoparticles with a diameter < 30 nm can be synthetized by
using the thermal decomposition of titanium alkoxide at 1200°Celsius
temperature. In another study, TiO2 nanoparticles with a diameter
(3–8 nm) were produced by pulsed laser ablation technique. In
addition, doped anatase TiO2 nanoparticles were produced by the solution
combustion method. Nevertheless, the disadvantages of this method
are the high cost, low yield, and difficulty in managing the structure and
morphology of the nanomaterials.

2.2.2.5 Templating Method
The process to construct materials with a similar morphology is known as
templating method. The production of nanomaterials which uses the
templating method has become exceptionally popular recently. This

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method uses the morphological characteristics with reactive deposition,
so it is possible to prepare numerous new materials with a regular and
controlled morphology by simply changing the morphology of the
template materials. Over the past few years, a variety of templates have
been developed to synthesize different nanomaterials. This method
has some shortcomings, like complicated synthetic procedures where
templates must be removed, normally by calcination technique, which
causes an increase in the manufacturing costs and also chances of
contamination.

2.2.2.6 Combustion Method
The combustion method includes a quick heating of a solution
comprising redox groups. This method leads to production of highly
crystalline nanoparticles with large surface areas. During production, the
temperature reaches to roughly 650°Celisus for 1–2 min to make the
crystalline materials.

2.2.2.7 Gas Phase Method
This method is good to produce thin film because it can be performed
chemically or physically. Nanomaterials are formed because of chemical
reaction or decomposition of a precursor in the gas phase. Moreover,
physical vapor deposition (PVD) is another technique which can be used
to produce thin film deposition. Interestingly, films are formed from the
gas phase method without using chemical transition. To produce TiO2
thin films, a beam of electrons heats the TiO2 material and the electrons
are produced and this process is recognized as Electron beam (E-beam)
evaporation. There are many benefits of making of TiO2 deposited with
E-beam evaporation than CVD method such as smoothness and better
conductivity.

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2.2.2.8 Microwave Radiation Method
Nanomaterials can also be produced by using microwave radiation and
there are several benefits of this method, like this method does not use
high temperature calcination for extended period of time and also is a
quick method of making crystalline nanomaterials. Moreover, high
quality of rutile rods can be created by joining hydrothermal and
microwave methods, while TiO2 hollow open- ended nanotubes can be
manufactured through reacting anatase and rutile crystals in the NaOH
solution.

2.2.2.9 Conventional Sol-Gel Method
This method has numerous advantages, for example, this method allows
impregnation or co-precipitation of nanomaterials, which can be used to
introduce dopants. To synthesize various oxide materials, sol-gel method
has been used, and this method allows better control for the texture
formation, the chemical reaction, and the morphological properties of the
solid materials. The major benefit of the Sol-Gel technique is the ability
to scale up with a high purity of nanomaterials. In Sol-Gel technique
process, a colloidal suspension is formed from the hydrolysis and
polymerization reactions of the precursors. These precursors are usually
inorganic metal salts or metal organic compounds. In addition, any factor
that effects either or both reactions are likely to impact the properties of
the gel formation and these factors are generally described as Sol-Gel
technique factors. These factors include type of solvent, water content,
acid or base content, and different type of precursor, precursor
concentration, and temperature. These factors affect the structure of the
initial gel formation. After this step, the wet gel can be mature in another
solvent. The time between the formation of a gel and its drying is known
as aging.

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2.3. Characterization of Nanoparticles
Nanoparticles occupy various application domains that are relevant to our
lives. According to the type of application, it is essential to characterize
NPs for their chemical, physical, and other properties. Different tools that
can be used to obtain these properties are in the next chapter. The
significant physical and chemical properties of NPs include their
composition, size and shape, and surface area as well as distribution,
stability, surface chemistry, roughness, and topography.

2.3.1 Electronic properties
The electronic properties of NPs depend on their size, surface area,
chemical composition, and modification. Modification of Al2O3 with
organic ligands can control the size of the materials produced through the
aggregation process. The presence of organic compounds such as ligands
can improve the different surface characteristics of NMs. Different types
of ligand monomers used can also have an effect on the structural
characteristics of the material produced, as seen in the modification of
Al2O3with organic ligands, which control the size of the materials
produced through the aggregation process. This kind of modification also
provides different electrical characteristics. As such, the electric
properties of the polymer nanocomposites were increased by the addition
of inorganic compounds to the polymer systems. Electrical properties,
such as electrical conductivity and the dielectric constant, could be
improved by the addition of barium titanate (BT) due to its perovskite
nanostructures and piezoelectric properties.

2.3.2 Optical properties
The optical properties of NPs, especially semiconductor materials, are
important for several applications, such as photocatalysts and
photovoltaics. The optical properties can be determined by basic light
18
principles and the Beer–Lambert law. The increased absorption of
wavelengths in semiconductor NPs are influenced by several factors, such
as size distribution, shape, sizes, and the type of modifiers. The optical
properties of Nd-doped NiO have been studied using UV–Vis
spectroscopy. Nd-doped NiO NPs could shift to a lower energy value
than pure NiO due to the exchange of electrons in the energy band and
the localized electron of Nd3+. Optical properties are influenced by the
composition of nanostructures, such as metal ion doping and surface
modification. Optical properties, especially the reflectance and scattering
phenomena, are affected by the particle size of NMs. The reflectance
increases with increasing particle size and decreases by increasing the
refractive index. Thus, the particle size can affect scattering particle
patterns when exposed to light, resulting in different spectral reflectance.

2.3.3 Magnetic properties
Magnetic NPs are used for applications in the medical and environmental
fields. Magnetic properties are influenced by the particle size of NPs with
the best performance showing a particle size of less than 35 nm. In single
compound NPs, the magnetic moment value of a molecule is represented
directly by the number of magnetic atoms, whereas for multicomponent
NPs, the magnetic value is determined by the number of lone pair
electrons according to the valence-shell electron-pair repulsion (VSEPR)
theory. Generally, the change in particle size is quite small and does not
change the lattice parameters of the metals. However, for metals that
contain metal oxides on the surface, the lattice parameters of metals may
change with changing particle size due to mismatches between the lattice
parameters of the metal and the metal oxides, which further causes
interfacial stress on the surface. Therefore, the magnetization value will

19
change with the change in particle size. Also, the magnetic properties are
influenced by other factors, such as the composition of the nanostructure
and the synthesis methods.

2.3.4 Mechanical properties
Nanoparticles have different mechanical properties compared to
microparticles or bulk materials. NMs provide a large surface area and
are easy to modify, resulting in an increase in mechanical properties such
as hardness, adhesion, stress and strain, and the elastic modulus. NPs
from a group of inorganic compounds show mechanical properties, while
organic compounds generally have low mechanical properties. Therefore,
increasing the mechanical properties of organic compounds is commonly
done by the addition of inorganic compounds. Bui et al. investigated the
mechanical properties of acrylic polyurethane by the addition of the metal
oxide SnO2. The presence of SnO2 in the polymer matrix improved the
mechanical properties, especially the hardness, impact and abrasion
resistance, and adhesion. However, the addition of more metal oxides to
the polymer matrix may reduce mechanical properties because the
presence of metal oxides can decrease the polymer–polymer interactions,
the polymer to metal-oxide interactions, and possible agglomeration
processes. Other studies have also reported that mechanical properties
depend on the size of the NPs.

2.3.5 Thermal properties
The thermal properties of NPs are better than their fluid form because
they have a large surface area and so heat transfers occur directly on the
surface of the material. The thermal properties of materials gradually
increased by increasing the metal oxide (SiO2) contents added to the
polycarbonate. The presence of metal oxides such as SiO2 can increase

20
interactions between NPs and polymers, along with restrictions in
polymer chain formation. The addition of a nanofiller, with a high
intrinsic thermal conductivity, influenced the thermal properties of NMs.
Overall, the thermal properties of NPs depend on the large surface area,
mass concentration, the ratio of energic atoms in NPs, and the fraction of
NP volume dispersed.

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 Chapter Three
Methods of detection of Nanomaterials: Techniques and Tool
3.1 Introduction
Nanomaterials have shown excellent physical, electrical, and chemical
properties compared to when they are in the bulk phase.
Nanotechnology/biotechnology is dealing with synthesis, characterization,
and applications of nanomaterials. The nanoscale materials contained tiny
particles, often known as nanoparticles and they require special
instrumentations and tools for their successful characterization and
analysis. In this chapter, we will describe briefly the tools and techniques
which are widely used for the characterization of nanomaterials. These
techniques include but not limited to scanning electron microscopy (SEM),
transmission electron microscopy (TEM), Fourier transform infrared
spectroscopy (FTIR), X-ray diffraction (XRD), energy-dispersive X-ray
(EDX) spectroscopy, thermal gravimetric analysis (TGA), dynamic light
scattering (DLS) analysis, density functional theory (DFT), zeta sizer, etc.
The illustration of each technique and some cases with graphics is
provided.

3.2 Scanning Electron Microscopy (SEM)

From the name, it is clear that the electron microscopes use electrons for
the formation of images instead of light as the case for optical microscopes.
The electronic image has often better image quality in terms of resolution
than optical microscopy, thanks to their small wavelengths. Scanning
electron microscope (SEM). SEM is a very useful technique to obtain the
surface topography and chemical composition of the specimens with a
wide view. SEM instrument along with a schematic of basic signals
produced in SEM are shown in (Figure 3.1).

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Figure (3.1): (a) Photograph of SEM instrument, showing its different parts
(b) basic signals produced in the SEM after interaction of primary electrons
with the specimen.
SEM instrument has the following basic parts: electron gun (top), electron
column (where electromagnetic lenses and coils are attached), chamber
(for specimen), detectors, and vacuum pumps (not shown in this figure). In
SEM, electrons are generated by an electron gun situated at the top of the
column and accelerated towards the specimen by applying a high voltage
(typically 20–30 kV). The gun electrons (called primary electrons) are then
focused by electromagnetic lenses while traveling through the column and
scan the specimen using electrical coils. Different kinds of signals such as
secondary electrons (SE), backscattered electrons (BSE), Auger electrons
(AE), X-rays, etc. are generated as energetic beam of electrons is subjected
to the specimen. These signals are then detected by the dedicated detectors
and produce electronic images or spectra as shown on the computer screen.
The SE signals are utilized to generate surface morphological images while
BSE and EDX signals are used to obtain chemical and structural
information of the specimen (see Figure 3.2).

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Figure (3.2): (a) SE image, (b) BSE image, and (c) EDX spectra of tungsten
carbide doped cobalt specimen (SEM working voltage: 15 kV). EDX
spectrum shows the contents of the specimen, e.g. C, O, Co, and W. W is
found to be a major constituent (~85 wt.%) of this compound. The scale
bars are 5 μm.
3.3 Transmission Electron Microscopy (TEM)
Transmission electron microscopy (TEM) is a powerful tool to attain a
high-quality data of the nanomaterials. The microscope that performs this
job is known as TEM instrument. In general, TEM is performed to obtain
a detailed morphology and structure of the specimen which is beyond the
limit of SEM. The main difference in SEM and TEM is that in TEM, the
electron beam is transmitted through a thin specimen, while in SEM, the
beam of electrons scans the surface of the sample instead of passing
through. Another important difference is the power of the microscope
(accelerating voltage; V). Typically, TEM is operated at 80–300 kV, this
power is much higher than SEM (maximum: 30 kV). Thus, TEM can

24
produce better images than SEM in terms of resolution. It is a worthy to
note that the wavelength (λ) of the electrons is related to V that can be
varied according to the following relation (λ = h/ ((2m0eV)1/2)); h is a
Planck’s constant, m0 is the rest mass, and eV is the energy of the electrons
provided by V. The reciprocal relationship between λ and V introduces a
very important concept: by increasing V, we can shorten the λ of the
electrons and hence improve the resolution. The λ of electrons in TEM is
comparable or smaller (λ = 0.00197 nm at 300 kV) than the size of the
atom (~ 0.1 nm) that helps TEM to reveal the finest details of the internal
structure of the specimen as small as individual atoms and molecules. The
main unit of TEM along with the basic interaction of electrons and
specimen is shown in Figure (3.3). TEM has the following basic parts:
electron gun (at the top), electron column, electromagnetic lenses,
apertures, sample holder, fluorescence screen (camera), vacuum pumps,
and high-tension tank (not shown in this figure). TEM has several modes
to collect the data but important imaging modes are bright- field (BF), dark-
field (DF), and high-resolution (HR) imaging, known as BF-TEM, DF-
TEM, and HR-TEM, respectively. Direct electrons are used to form the BF
imaging after blocking the scattered electrons by objective aperture and
vice versa for DF-TEM. HR-TEM is performed using the phase of the
electrons and acquired a detailed structure of the specimens down to
the atomic level. The working principle of TEM is based on the interaction
between incident electrons and specimen. In TEM, high energy electrons
are accelerated towards the specimen by applying a high voltage (80–
300 kV). These electrons are focused by a system of condenser lenses. A
fine focused beam of electrons is then transmitted through the thin sample.
Typically, the suitable thickness of the specimen is about 100 nm for
material science samples and 200 nm for biological specimens. The
transmitted electrons are generally of two types: direct electrons (do not

25
change their direction) and scattered electrons that changed their trajectory
after passing through the sample. Either type of electrons can be utilized to
make the image. If the image is made by direct electrons, then it is known
as BF image (see Figure 3.3). On the other hand, if the scattered electrons
are allowed to pass through the objective aperture for the purpose of
the image and blocked the direct electrons, then it is called DF image.

Figure (3.3): Two imaging modes of TEM: (a) BF and (b) DF imaging.
The carbon hole that has bright contrast in BF turned to dark (inverse) in
DF (working voltage: 200 kV). The scale bars are 1 μm.

The important difference between the two images is the contrast that is
opposite; for example, the bright features of BF image (such as holes of
carbon support film) will appear dark in DF image and vice versa. TEM
image (either made by direct or scattered electrons) can be viewed on the
fluorescence screen or recorded by a computer using a digital camera.
Notably, images formed by TEM have proven better resolution than SEM
due to the basic principle of TEM (transmission of electrons) and because
of the high energy of electrons.

26
3.4 Fourier Transform Infrared (FTIR) Spectroscopy

Fourier transform infrared (FTIR) is an infrared spectroscopy technique to
study the molecular bonding of the organic/inorganic materials. IR is a
region of electromagnetic radiations between the red edges of the visible
spectrum at a wavelength of 700 nm to 1 mm, i.e. IR waves are longer than
visible light while shorter than radio waves (see Figure 3.4 a). During
FTIR, a specimen is exposed to IR radiations in order to create a spectrum
of the specimen. A portion of the radiations is transmitted, while the
rest of the radiations are absorbed by the specimen depending on the nature
of bonding in the material. A molecular fingerprint of the specimen is
created as a result of transmission and absorption at a molecular level. A
wide range of information, such as identifying the material properties,
quality of the specimen, and number/ratio of the individual ingredients in
a mixture can be extracted by FTIR spectra.

Figure (3.4): (a) Electromagnetic radiation spectrum where wavelengths
range for IR region is from about 700 nm to 1 mm. (b) Schematic of
working of FTIR instrument along with FTIR spectrum.

27
3.4.1 Main Components of FTIR Instrument
The following are the main parts of the FTIR instrument:
1. Source: The source to emit the IR energy in the form of a beam.
2. Interferometer: A distinctive signal (interferogram) containing all the IR
frequencies is produced by the interferometer. The interferogram signal is
created as a result of the interference of two beams and contains the
information of each IR frequency. Measuring the interferogram means
a simultaneous measurement of all IR frequencies.
3. Sample Chamber: The sample is mounted into the specimen chamber.
The IR beam goes into the chamber for specimen interaction. Only specific
frequencies of the IR signal are absorbed/transmitted depending on the
nature of the specimen.
4. The Detector: A special-purpose detector is designed to gauge the
interferogram signal.
5. The Computer: To analyze the signal for identification purposes, a plot
of each IR frequency is required. Therefore, the interferogram is decoded
into the individual frequencies in a computer using a mathematical
formulation, known as Fourier transform.

3.4.2 Working of FTIR Instrument
In FTIR instrument, radiations are produced by an IR light source in the
form of a beam. The beam of energy then travels through the interferometer
for spectral encoding. The interferogram is created as a result of spectral
encoding. The working of interferometer and creation of FTIR plot is
described as follows (see Figure 3.4 b). Firstly, the beam splitter (a
partially reflecting mirror) of the interferometer divides the incoming
radiations into two beams. These two beams are then reflected from two
separate mirrors, one of the mirrors is fixed and the other is moveable.
After reflecting from respective mirrors, both beams are merged back at
the beam splitter. Now, the IR beam goes into the specimen chamber. The
signal from the interferometer is the result of interference of these two
beams and is known as the “interferogram.” Interferogram contains the

28
information of each IR frequency that is falling on a specimen from the
source. The beam is either passed through or bounces off the specimen
surface, depending on the analysis requirement. A desired range of IR
frequencies representing a distinctive property of the specimen is absorbed.
The interferogram signal is detected by a special purpose detector and
decoded in the computer to transform into a meaning data using a
mathematical tool known as Fourier transformation. After the signal
transformation, FTIR signal in the form of spectrum is available for
manipulation and expositions. FTIR spectrocopic characterization can be
used to analyze several kinds of materials.

3.5 X-Ray Diffraction (XRD)
X-ray diffraction (XRD) is a non-destructive method to study the
material’s structure at the molecular and atomic level. XRD is the best
method to investigate the crystalline, polycrystalline, and non-crystalline
(amorphous) materials. The wavelengths (λ) of the X-rays (used in the
XRD) are in the range of nanometers. XRD is the elastic scattering (no-
loss of energy during a collision) of X-rays by atoms of the materials. The
principle of XRD is based on the interference of scattered waves. The
resultant amplitude (intensity) of the scattered waves depends on the
difference in the distance traveled by the waves, i.e. path difference (phase
or angle). If the two waves superimpose in such a way that they are in phase
(same crusts and troughs), then the resultant intensity is the sum of the two
intensities, the phenomenon is known as constructive interference. On the
other hand, in the destructive interference, two out of phase waves merged
and the resultant intensity is the difference of two intensities. XRD
analyzer plotted the x–y plot (XRD pattern) between intensity (in arbitrary
units) and scattering angle, 2θ (degrees). The XRD pattern is analyzed by
a mathematical formulation, known as Bragg’s law and the following

29
information can be obtained such as nature of material, atomic
arrangement, crystallite size, chemical composition, etc. The XRD line
patterns of more than 60,000 different crystallographic phases are available
in the electronic database: JCPDS (Joint Committee on Powder Diffraction
Standards). The PDF file (example: JCPDS No. 19-0628) consists of three
most strong characteristics lines of the existing phase. The XRD technique
applies to specimens of powders, thin films and solids.

3.5.1 Main Components of XRD Instrument
1- X-Rays Tube: A beam of fast-moving electrons is collided with atoms
of a metallic target (copper) to produce X-rays in the tube.
2- Collimator: A collimator is used to make the rays parallel before they
hit the specimen.
3- Sample Stage: Specimens are placed in the sample stage.

4- Detector: The diffracted beam of X-rays is detected by a counter.

5- Computer: The collected data is later plotted in the form of XRD pattern
(2θ versus reflection intensity) on a computer.

3.5.2 Working of XRD Instrument
In XRD, a collimated beam (thin and parallel beam) of X-rays is directed
towards a sample. The incoming beam of rays interacts with atoms of the
specimen and scattered outward direction. Angle made by an incoming
beam with the surface of the specimen is θ, then the angle of the diffracted
beam is 2θ; 2θ is dependent on arrangement of the atoms and type of atoms,
etc. The diffracted beam is then detected by a detector and sent to a
computer for making an XRD pattern (see Figure 3.5 a). Now, for a given
specimen consider several periodic lattice planes (atomic layers) where
each layer is separated by d (inter-plane spacing). According to Bragg’s
Law, constructive interference occurs when the path difference is

30
 an integral number of wavelengths. We can describe this law as follows:
AB = d sin θ, and BC = d sin θ, then path difference is (AB + BC) = 2d sin
θ. According to the Bragg’s laws, a constructive interface occurs when 2d
sin θ = n λ is satisfied (Figure 3.5 b), where n is an integer, λ is
the wavelength of the X-ray beam, and θ is the angle between the incident
beam and the normal to the sample planes.

Figure (3.5): (a) Schematic representation of working of XRD
instrument along with XRD pattern. (b) A 2-D crystal lattice and a set
of imaginary planes. Constructive interference occurs when the path
difference (AB + BC = 2d sin θ) is equal to integral multiple of
wavelength (nλ) (Bragg’s law of diffraction).
In general, for wider interparticle distance d, the scattering angle 2θ is lower.
This means that the planes with wider d appeared earlier in the XRD patterns
where scattering angle is low. In XRD, the angle of the incident beam is
varied to obtain all the possible reflections for a given sample. By measuring
θ, d of every single crystallographic phase can be determined by comparing
the data with the standard line patterns available in the Powder Diffraction
File (PDF) database.
31
 Chapter Four
Applications, Advantages and Disadvantages
Of the Nanomaterials
4.1 Introduction
In this chapter we will outline several of the many applications of nanomaterials,
both current and anticipated. To our knowledge, there is no comprehensive review
of nanotechnology applications, likely due to the rapid development of this field.
We feel that this chapter is necessary in order to broaden understanding of the
importance that nanomaterials have and will play in our future, improving the
quality of life through nanomedicine, electronics, and other nano-fields. Among
the established applications of nanomaterials, we give as examples:
microelectronics, synthetic rubber, catalytic compounds, photographic supplies,
inks and pigments, coatings and adhesives, ultrafine polishing compounds, UV
absorbers for sun screens, synthetic bone, ferrofluids, optical fiber cladding, and
cosmetics. Applications currently entering widespread use include: fabrics and
their treatments, filtration, dental materials, surface disinfectants, diesel and fuel
additives, hazardous chemical neutralizers, automotive components, electronics,
scientific instruments, sports equipment, flat panel displays, drug delivery
systems, and pharmaceutics. The unique properties of nanomaterials encourage
belief that they can be applied in a wide range of fields, from medical applications
to environmental sciences. Studies conducted by nanotechnology experts
mapping the risks and opportunities of nanotechnology have revealed enormous
prospects for progress in both life sciences and information technology.
Medical applications are expected to increase our quality of life through early
diagnosis and treatment of diseases, and prosthetics, among others. Ecological
applications include removal of persistent pollutants from soil and water supplies.
Nanotechnology has become a top research priority in most of the industrialized
world, including the USA, the EU and Japan. In the U.S.A. nanotechnology is

32
now at the level of a federal program. Since 2000, around 60 countries have
initiated nanotechnology based initiatives at a national level.

4.2 Electronics
4.2.1 Microelectronics: Many of the current microelectronics applications are
already at a nanoscale. During the last four decades, the smallest feature of a
transistor shrunk from 10 µm down to 30 nm. The ultimate objective of
microelectronics fabrication is to make electronic circuit elements that are
nanoscopic. For example, by achieving a significant reduction in the size of circuit
elements, the microprocessors (or better said, nanoprocessors) that contain these
components could run faster and incorporate more logic gates, thereby enabling
computations at far higher speeds. CNTs are exciting alternatives to conventional
doped semiconductor crystals due to their varied electronic properties, ranging
from metallic, to semiconducting, to superconducting.

4.2.2 Displays: The resolution of a television or a monitor improves with
reduction of pixel size. The use of nanocrystalline materials can greatly enhance
resolution and may significantly reduce cost. Also, flat-panel displays constructed
with nanomaterials may possess much higher brightness and contrast than
conventional displays owing to the enhanced electrical and optical properties of
the new materials. CNTs are being investigated for low voltage field-emission
displays. Their combination of mechanical and electrical properties makes them
potentially very attractive for longlife emitters.

4.2.3 Data storage: Devices, such as computer hard-disks function based on their
ability to magnetize a small area of a spinning disk to record information, are
established nano-applications. Discs and tapes containing engineered
nanomaterials can store large amounts of information. Future avenues for
magnetic recording that will drastically increase the capability of data storage
include spintronics and nanowires.

33
4.2.4 High energy density batteries. New nanomaterials show promising
properties as anode and cathode materials in lithium-ion batteries, having higher
capacity and better cycle life than their larger-particle equivalents. Among them
are: aerogel intercalation electrode materials, nanocrystalline alloys, nanosized
composite materials, carbon nanotubes, and nanosized transitionmetal oxides.
4.2.5 High-sensitivity sensors: Due to their high surface area and increased
reactivity, nanomaterials could be employed as sensors for detecting various
parameters, such as electrical resistivity, chemical activity, magnetic
permeability, thermal conductivity, and capacitance.

4.3 Transportation and telecommunication
4.3.1 Car tires: Nanoparticles of carbon black ranging between 10 nm - 500 nm
act as a filler in the polymer matrix of tires, and are used for mechanical
reinforcement.
4.3.2 Car bumpers: Clay particle based composites containing plastics and nano-
sized clay are used to make car exteriors that are lighter and twice as resistant to
scratches as usual materials.
4.4 Imaging
4.4.1 Scanning microscope imaging: SWCNTs have been used as probe tips for
atomic-force microscopy imaging of antibodies, DNA, etc. Nanotubes are ideal
probe tips for scanning microscopy due to their small diameter (which maximizes
resolution), high aspect ratio, and stiffness.
4.4.2 Molecular-recognition AFM tips: SWCNTs with attached biomolecules
are attached to AFM tips, and used for “molecular-recognition” in order to study
chemical forces between molecules.

34
4.5 Biomedical applications
4.5.1 Nanoscaffolds: Nanofiber scaffolds can be used to regenerate central
nervous system cells and possible other organs. Experiments performed on a
hamster with severed optic tract demonstrated the regeneration of axonal tissue
initiated by a peptide nanofibers scaffold.
4.5.2 Antimicrobial nanopowders and coatings: Certain nanopowders, possess
antimicrobial properties. When these powders contact cells of E. coli, or other
bacteria species and viruses, over 90% are killed within a few minutes. Due to
their antimicrobial effect, nanoparticle of silver and titanium dioxide (