Book Volume 1
Preface
Page: i-ii (2)
Author: Virat Khanna, Suneev Anil Bansal, Vishal Chaudhary and Reddicherla Umapathi
DOI: 10.2174/9789815238846124010001
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Electron Microscope: The Tool for Qualitative and Quantitative Analysis of Nano-Materials
Page: 1-23 (23)
Author: Lankipalli Krishna Sai, Tadisetti Taneesha and Sunil Kumar Pradhan*
DOI: 10.2174/9789815238846124010003
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Abstract
An electron microscope is a highly advanced sophisticated tool where high
energy electron beam is used as the source. Since an electron beam has a shorter
wavelength than visible light photons, it may expose the structure of tiny objects and
has a higher resolving power than a light microscope. While most light microscopes are
constrained by diffraction to around 500 nm resolution and usable magnifications
below 2000, a scanning electron microscope (SEM) may attain 5 nm resolution and
magnifications up to roughly 10,000,000. Electromagnetic lenses, which are similar to
the glass lenses of an optical light microscope, are used in electron microscopes to
create electron optical lens systems. Large molecules, biopsy samples, metals, crystals,
and other biological and inorganic specimens, among others, can all have their ultrafine structure studied using electron microscopes. Electron microscopes are frequently
used in industry for failure analysis and quality control. The images are captured using
specialised digital cameras and frame grabbers by modern electron microscopes to
create electron micrographs. To create an appropriate sample from materials for an
electron microscope, processing may be necessary. Depending on the material and the
desired analysis, a different procedure is needed. Transmission electron microscopes
(TEM), scanning electron microscopes (SEM), reflection electron microscopes (REM),
scanning tunnelling microscopes (STM), and other types of electron microscopes are
commonly employed in academic and research institutions. The initial and operating
costs of electron microscopes are higher and they are also more expensive to construct
and maintain. High-resolution electron microscopes need to be kept in sturdy structures
(often underground) with specialised amenities like magnetic field cancelling devices.
Amelioration of Perovskite Nanomaterials for Advance Energy Applications
Page: 24-48 (25)
Author: Muhammad Salman Habib* and Muhammad Asif Rafiq
DOI: 10.2174/9789815238846124010004
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Abstract
The demand of energy highlight the need to explore new energy resources
with less emissions without depleting the environment. With this perspective, novel
perovskite lead-free materials are taking over the conventional energy systems of fossil
fuels that produce carbon in the environment. It has been years of struggle that
scientists are working on materials for more energy with less waste materials. The
challenge was readily accepted by perovskite nanomaterials that can generate energy,
store it, and use it when required. The development of these nanomaterials with their
promising properties such as dielectric coefficient, superconductivity, and
sustainability at high temperatures, withstand high mechanical properties and can be
coated, pasted, or in the form of thin and thick films. This can be done by the solidstate reaction (SSR) mixing the metallic oxides in a fixed ratio in ball milling by wet or
dry method. The composites prepared were calcined, pressed, and sintered at high
temperatures. Following the characterization to check the properties make them
superior for high-energy advanced applications. The perovskite nanomaterials’
composites can be utilized perfectly for hydrogen generation and production,
photocatalysis reactions, photovoltaic solar cells, solid oxide fuel cells, electrolysis,
supercapacitors, sensors, actuators, structural health monitoring applications and
metal-air batteries. This chapter covers the application-based synthesis,
characterizations, and properties of the perovskite nanomaterials for high-energy
applications.
Copper Oxide Nanoparticles in Oil and Gas Industries: Current Developments
Page: 49-74 (26)
Author: Mhd Hazli Rosli, Nur Farahah Mohd Khairuddin, Mohamed Abdelmonem and Che Azurahanim Che Abdullah*
DOI: 10.2174/9789815238846124010005
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Abstract
This chapter presents an in-depth analysis of Copper oxide nanoparticles
(CuONPs) and their emerging role in the oil and gas industry. Over the past five years,
nanomaterial technology, especially CuONPs, has attracted significant attention due to
its diverse applications in fields like petroleum. In the context of the oil and gas
industry, CuONPs have been revolutionary, particularly in enhancing oil recovery
(EOR) and as innovative drilling fluids. Their application leads to more efficient
extraction and reduced viscosity of trapped oil. The synthesis of CuONPs has evolved,
with biological methods standing out for their cost-effectiveness, safety, and
environmental friendliness. These green synthesis methods have redefined industry
standards by offering a sustainable alternative to traditional physical and chemical
approaches. The chapter aims to provide a comprehensive overview of the practical
applications of CuONPs in the oil and gas sector, emphasizing their production through
green routes. It also addresses the challenges and prospects of CuONPs, setting a
foundation for further research and technological advancements in this field.
Combating Hot Corrosion of Metallic Substrate by Nano-Coating
Page: 75-103 (29)
Author: Santosh Kumar*
DOI: 10.2174/9789815238846124010006
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Abstract
Corrosion of metallic materials poses a serious threat to the efficiency of the
manufacturing and construction industries. To overcome this, various surface
modification techniques are employed. But, surface protection by nano-coating is
gaining great potential owing to its numerous benefits. These include surface hardness,
high-resistance against hot corrosion, high wear resistance, and adhesive strength.
Additionally, nano-coatings can be deposited in thinner and smoother thicknesses,
allowing for increased efficiency, more flexible equipment design, smaller carbon
footprints, and lower operating and maintenance costs. Hence, the aim of this chapter is
to provide an overview of the corrosion performance of ceramic, metallic, and
nanocomposite coatings on the surface of the metallic substrate. In addition, the role of
nanocoating to combat corrosion of metallic substrate is explored. Finally, the diverse
applications of nano-coating in different fields including aircraft, automobile, marine,
defense, electronic, and medical industries are discussed.
Agro-Nanotechnology: A Way Towards Sustainable Agriculture
Page: 104-123 (20)
Author: Aquib Khan and Faria Fatima*
DOI: 10.2174/9789815238846124010007
PDF Price: $15
Abstract
Addressing the global population's dietary needs is crucial amid crop
damage issues like insect infestations and adverse weather affecting one-third of
conventionally farmed crops. Nanotechnology, recognized for its efficacy and
environmental benefits, has gained attention in the past decade. While it has
transformed medicine, its applications in agriculture are underexplored. Current
research investigates the use of nanomaterials in agriculture for targeted delivery of
genes, insecticides, fertilizers, and growth regulators. Nanotechnology shows promise
in mitigating abiotic stress in plants by mimicking antioxidative enzymes. This chapter
assesses nanoparticles' roles in plant research, highlighting their effectiveness as
growth regulators, nanopesticides, nanofertilizers, antimicrobial agents, and targeted
transporters. Understanding plant-nanomaterial interactions opens new avenues for
enhancing agricultural practices, improving disease resistance, and crop productivity,
and optimizing fertilizer use.
The Effect of Economic Natural Dyes on the Performance and Efficiency of TiO2 NanoStructure Solar Cells
Page: 124-144 (21)
Author: Nada M. O. Sid Ahmed*, Nodar. O. Khalif, Manahil E. Mofdal and Nada H. Talib
DOI: 10.2174/9789815238846124010008
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Abstract
The aim of this research can be divided into two stages. The first stage is to
synthesize and find a simple and less expensive method to produce titanium dioxide
nanostructures with optimum properties that can be used in the construction of lowcost, nanoparticle-based solar cells as a replacement for custom silicon solar cells. The
second stage is to determine the effect of natural dyes on the performance and
efficiency of TiO2
nano-structure dye synthesized solar cells (TiO2
DSSC) via spin
coating. In order to improve and enhance the performance and efficiency of dye solar
cells, thin film TiO2
nanostructure was synthesized using the sol-gel process, which is
simple and inexpensive. Afterward, different natural dies were introduced in the
fabrication process over the TiO2
layer also via spin coating. The function of the dye is
to confine a sufficient amount of light, for optimum performance and power conversion
efficiency. In the last fabrication step, graphite contacts were evaporated on the top dye
layer. The I-V characteristics of the different dyes were studied and the structural
properties of the TiO2
nanostructures were investigated through an X-Ray Diffraction
(XRD) pattern. The TiO2
nanoparticles’ morphology and particle size were determined
by a scanning electron microscope (SEM), while the optical band gap energy was
found by employing UV-VIS-NIR diffuse absorption spectroscopy. Three types of
natural dye were used which were Roselle, curcumin, and black tea and their
conversion efficiencies were 8.46, 6.94, and 6.33 respectively, which is considered
acceptable compared to the results obtained by other researchers.
Investigation of the Effect of Annealing Conditions on Chemical Bath Deposited CdTe Thin- film from Non-Aqueous Bath
Page: 145-161 (17)
Author: Sudeshna Surabhi*, Kumar Anurag and S. R. Kumar
DOI: 10.2174/9789815238846124010009
PDF Price: $15
Abstract
This research investigates the consistency of chemical bath deposition (CBD)
for CdTe thin films. Films were deposited using tellurium dioxide and cadmium acetate
in a non-aqueous medium at 160°C. The impact of subsequent annealing on the optical,
structural, and surface properties of these films was examined. XRD, FTIR, UV-Vis,
SEM, and photoluminescence techniques were used to characterize the films. EDS
analysis revealed a Cd:Te ratio of 1.27 before annealing, which improved to 1.06
(closer to the ideal 1:1 ratio) after annealing. The average crystallite size of annealed
CdTe film was around 25nm. Photoluminescence peaks were observed at 566 nm and
615 nm.
Applications, Biomedical Necessities, and Green Future of Metallic Nanoparticles
Page: 162-184 (23)
Author: Jyoti Bhattacharjee and Subhasis Roy*
DOI: 10.2174/9789815238846124010010
PDF Price: $15
Abstract
Metallic nanoparticles like gold nanoparticles (AuNPs), magnetic iron oxide
nanoparticles (Fe3O4
), and cysteine-capped silver nanoparticles (Cyanopes) are
changing the face of green nanotechnology. Their photonic capabilities, ultrafine size (
10-100 nanometers), biocompatibility, diamagnetic strength, antibacterial activity, and
photochemical qualities make them extremely useful in medical applications,
radiotherapies, drug delivery, cosmetics, and solar cell coatings. This chapter provides
a comprehensive outlook on the applications, biomedical necessities, and green future
of metallic nanoparticles. The current discussion revolves around graphene-based
nanofillers, focusing on their ability to enhance the tribological properties of aluminum
and its alloys within the realm of materials research. Thin metallic tin sulfide
nanoparticles and titanium oxide nanorods, on the other hand, play an important role in
photochemical water splitting. Modern nanotechnology is advancing biological
processes by allowing for a thorough examination of metallic nanoparticle forms as
highlighted in the chapter. A notable application incorporates a nanoscale metallic
lattice that facilitates the transfer of cisplatin and siRNA, showing great promise in resensitizing ovarian tumors. This chapter provides an exhaustive analysis of the
potentials, benefits, and challenges associated with metallic nanoparticles, emphasizing
their extensive applications and crucial role in the advancement of various fields.
Silver Nanoparticles with Enhanced Cytotoxicity and Biological Activity Produced from Green Methods
Page: 185-202 (18)
Author: Celin. S. R.* and R. Ajitha
DOI: 10.2174/9789815238846124010011
PDF Price: $15
Abstract
Research in the fields of physics, chemistry, and engineering is all facing
more important challenges as a result of the rapid development of nanotechnology. The
green synthesis of metallic nanoparticles opened the door for improvements and
protections to be made to the environment by lowering the amount of harmful
chemicals used and avoiding the biological dangers that were present in biomedical
applications. Simple, fast, and environmentally friendly, plant-mediated production of
metal nanoparticles is rising in popularity. We show an easy and environmentally
friendly way to make silver nanoparticles using biomolecules found in an aqueous
extract of the leaves of the plant Kalanchoe gastonis-bonnieri. No other chemicalreducing or stabilizing agent is needed in this way. The reaction is carried out in an
aqueous solution in a process that is benign to the environment. This chapter examines
the anti-oxidant, diabetic, inflammatory, cancer, and cytotoxic properties of silver
nanoparticles that were generated utilizing the aqueous extract of the leaves of the plant
Kalanchoe gastonis-bonnieri. The results of the investigation are presented and
discussed in this chapter.
Recent Methods for Biogenic Synthesis of Metal Nanoparticles and their Applications
Page: 203-224 (22)
Author: Giriraj Tailor*, Jyoti Chaudhary, Chesta Mehta, Saurabh Singh and Deepshikha Verma
DOI: 10.2174/9789815238846124010012
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Abstract
Nanoparticles are among the most important tools under investigation due to
their application in optical, electrical, biological, sensing, and photocatalytic systems.
Nanoparticles made by plants have a larger range of sizes and shapes and are far more
stable. Investigators' fascination with producing metal-based nanoparticles, such as
those of silver (Ag), platinum (Pt), gold (Au), zinc (Zn), copper (Cu), and cerium (Ce),
has been aroused by the study of biological systems. In a manner analogous to this,
microorganisms produce valuable substances like antibiotics, acids, and pigments as
well as proteins and bioactive metabolites. The plant-based synthesis uses a variety of
extracts, including fruit, leaves, roots, peel, bark, seeds, twigs, stems, shoots, and
seedlings. The primary theme of the chapter is the synthesis of metallic nanoparticles
mediated by plants. The potential applications of nanoparticles across a variety of fields
have altered the research and industries that are briefly discussed in this chapter.
Performance Benchmarking of Different Convolutional Neural Network Architectures on Covid-19 Dataset
Page: 225-247 (23)
Author: Harsh Kumar Mishra, Anand Singh and Ayushi Rastogi*
DOI: 10.2174/9789815238846124010013
PDF Price: $15
Abstract
The utilization of chest X-rays could offer valuable assistance in the initial
screening of patients before undergoing RT-PCR testing. This potential approach holds
promise within hospital environments grappling with the challenge of categorizing
patients for either general ward placement or isolation within designated COVID-19
zones. This study investigates the use of chest X-rays as a preliminary screening
technique for suspected COVID-19 cases in hospital settings, given the limited testing
capacity and probable delays for RT-PCR testing. We assess how well several neural
network architectures perform in automated COVID-19 identification in X-rays with
the goal of locating a model that has the highest levels of sensitivity, low latency, and
accuracy. The results reveal that InceptionV3 exhibits better robustness while
MobileNet obtains the maximum accuracy. This strategy may help healthcare
organisations better manage patients and allocate resources optimally, especially when
radiologists are hard to come by. This will help in choosing an architecture that has
better accuracy, sensitivity, and lower latency. The chosen models are pre-trained using
the technique of transfer learning to save computation power and time. After the
training and testing of the model, we observed that while MobileNet gave the best
accuracy among all the models (VGG16, VGG19, MobileNet and InceptionV3),
IncpetionV3 was still better when it comes to robustness.
Application of Novel Nanotherapeutic Strategies in Treatment Using Herbal Medicines
Page: 248-270 (23)
Author: Sumanta Bhattacharya*
DOI: 10.2174/9789815238846124010014
PDF Price: $15
Abstract
Herbal remedies are gaining popularity as an alternative to allopathic
medicine because of how much better they are at curing modern health problems. By
facilitating the efficient distribution of medicinal molecules to both targeted and nontargeted regions, nanotherapeutic approaches enhance the pharmacokinetic efficacy of
herbal remedies. Active and system-based nanostructures have the potential to utterly
transform herbal therapy. Nanomedicine may benefit from third-generation
nanotechnology, namely system-based nanostructures, due to their self-healing
properties. Research and Market predicts that the pharmaceutical market's use of
nanotechnology will increase by 15.3% by 2026. The effectiveness of dual therapy
treatment is enhanced by nanotechnology. The creation of cell-penetrating peptides,
which allow the transport of drug molecules to the afflicted cells, is made possible by
nanotechnology. The rate of medication metabolism is accelerated by nanomaterials.
The use of nanotechnology to enhance histidine activity has significant implications for
the treatment of cancer and acute genetic disorders. Acute illnesses such as cancer,
genetic disorders, neurological disorders, behavioural disorders, cardiovascular
disorders, and bone fractures can all benefit from a nanotherapeutic approach to
treatment. Nanomedicines' market share is growing at an exponential rate because of
their superior therapeutic efficacy. Increased access to Ayurvedic treatment will result
from nanotechnology's ability to boost the efficacy of herbal remedies. Waste
management is further supported by the use of nanotechnology, which enhances the
ability to extract bioactive components from plant-based waste products. Due to the
dynamic nature of infectious illnesses, nano vaccines work more effectively than
traditional vaccinations. This chapter will describe research on the use of
nanotechnology in various ayurvedic practices, which will broaden the use of herbal
remedies for the treatment of long-term health problems. Additionally, it will
investigate the potential of nanomaterials to enhance the efficacy of herbal remedies,
which can aid in the development of novel ayurvedic treatment approaches.
Subject Index
Page: 271-276 (6)
Author: Virat Khanna, Suneev Anil Bansal, Vishal Chaudhary and Reddicherla Umapathi
DOI: 10.2174/9789815238846124010015
PDF Price: $15
Introduction
Recent Advancements in Multidimensional Applications of Nanotechnology provides a comprehensive overview of the latest advancements and applications of nanotechnology across various dimensions. Covering a wide range of topics, from electron microscopy to nanotherapeutic strategies, the book explores the diverse applications of nanotechnology in industries and research fields. Key Features: Comprehensive Coverage: Gain insights into electron microscopy, biogenic synthesis methods, energy applications, and more. Industry Applications: Discover how nanotechnology is revolutionizing industries such as energy, oil and gas, agriculture, and healthcare. Cutting-Edge Developments: Stay ahead of the curve with discussions on copper oxide nanoparticles, nano-coatings, and thin film optimization for solar cells. Biomedical Breakthroughs: Explore the exciting realm of biomedical applications, from metallic nanoparticles in healthcare to biogenic synthesis methods. Practical Insights: Benefit from practical insights and case studies that showcase real-world applications of nanotechnology.