Foreword
Page: i-ii (2)
Author: Victor Sunday Aigbodion
DOI: 10.2174/9789815223101124030001
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Preface
Page: iii-vii (5)
Author: Dibya Prakash Rai, Kingsley O. Obodo and Jitendra Pal Singh
DOI: 10.2174/9789815223101124030002
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Role of Plasmonic Metal-semiconductor Heterostructure in Photo Catalytic Hydrolysis and Degradation of Toxic Dyes
Page: 1-37 (37)
Author: Shomaila Khanam and Sanjeeb Kumar Rout*
DOI: 10.2174/9789815223101124030004
PDF Price: $30
Abstract
Plasmonic metal-semiconductor heterostructure has become the most
prominent content for water splitting by photocatalytic means. It is thought to be an
effective, clean, and affordable energy source. Hydrolysis, water splitting, and
destruction of organic dyes have all demonstrated the high efficiency of LSPR
formation by these materials. A noble metal combined with a low bandgap
semiconductor makes for the perfect photocatalyst. In this case, both semiconductors
and noble metals can absorb visible light. They are prone to producing positive and
negative pairs and inhibit their recombination, causing the resulting electron-hole pairs
to interact with the chemicals in the immediate environment, thereby increasing
photocatalytic activity. The strong SPR's combined effect with the efficient separation
of photogenerated electrons and holes supported by noble metal particles can be
credited with the increased photocatalytic activity. It has become a useful method for
overcoming the limitations of conventional photocatalysts and promoting
photocatalytic mechanisms.
This book chapter has three main goals: briefly describing plasmonic dynamics,
explaining the preparation techniques, analyzing the key characteristics of the
plasmonic metal nanostructure that influence photocatalysis, summarizing the reported
literature, and offering an in-depth explanation of the four fundamental plasmonic
energy transfer process.
BaZrO3-Based Ceramics and Ceramic Composites as Smart Materials for Advanced Applications
Page: 38-94 (57)
Author: D. Vignesh and Ela Rout*
DOI: 10.2174/9789815223101124030005
PDF Price: $30
Abstract
Ancient human history invites significant learning with unknowing facts and
fascinations. Significant development and transitions in the human lifestyle are
visualized from the capitalized materials. “Ceramics”, as antique as it sounds, is
frequently used for innumerable applications. From pottery to pellets, ammunition to
antennas, electrolytes to electronics, all exist under the radar of ceramic materials. The
dominant trait of ceramic materials for advanced applications is constantly replenished
to extract peerless products for future utilization. Ionic or covalent bonding in ceramic
microstructures administers their suitable mechanical, electrical and chemical
characteristics. Pristine ceramics display low conductivity and chemical stability, while
doped ceramics via implanted impurities empower their characteristics. The nature of
dopants and defect substitution differs on the target application. The vastly introspected
energy sector is permeated with acceptor-doped perovskite ceramics, while the defense
sector inquests over piezoelectric ceramics and ceramic composites. The trivial facet
amongst all is the use of Barium Zirconate (BaZrO3
) based ceramic compositions. It
has been substantially contemplated to visualize the role played by BaZrO3
in multiple
domains. Either as a parent material or as an additive, BaZrO3
attracts research groups
from diverse sectors. Compiled with innumerable advantages, it accompanies a few
limitations. The vital thing is the high sintering temperature along with the trade-off
between proton conductivity and chemical stability. However, BaZrO3
-based ceramics
are keenly monitored and tailored in an attempt to subsidize the maximum possible
drawback with a simultaneous improvement in their properties. In the following
chapter, we emphasize BaZrO3
-based ceramic and ceramic composites as smart
materials for advanced applications. The extended applications in the energy sector,
photocatalysts for hydrogen production, smart bullet systems in defense and microwave
dielectric resonators for wireless communications are elaborately introspected with key
insights.
A High-capacity Anode Material for Lithium-ion Batteries is Sili-graphene Type SiC3
Page: 95-108 (14)
Author: M. Houmad*, M. Khuili, A. El Kenz and A. Benyoussef
DOI: 10.2174/9789815223101124030006
PDF Price: $30
Abstract
In this study, we have proposed an anode material based on Silicon doped
graphene (Siligraphene) for developing the Li-ion batteries (LIBs). We have predicted
that Siligraphene can be an anode material for lithium batteries. In particular, we have
found that the Siligraphene sheet can adsorb lithium atoms in different sites in a
hexagonal structure. Also, we have found that Lithium atoms can be diffused along the
plane of siligraphene. The energy of diffusion of siligraphene (SiC3
) is about 0.095eV,
and for Li on top of silicon atoms is about 0.223eV, indicating rapid
charging/discharging processes. During charging and discharging, the electrode LixSiC3
exhibits small variations in voltage, making them a potential candidate for Li-ion
batteries.
An Introduction to the Fabrication of White Lightemitting Diodes
Page: 109-142 (34)
Author: Naorem Premjit Singh* and Yengkhom Rangeela Devi
DOI: 10.2174/9789815223101124030007
PDF Price: $30
Abstract
Light-emitting diodes, especially white light-emitting diodes are very
attractive and fascinating lighting sources at this present time because they have the
potential for high energy saving and environmental friendliness as compared to
conventional lighting sources such as incandescent and fluorescent lamps and also have
wide applications in a variety of fields including in lighting, architectural and medical
etc. Among the various applications, the lighting sector is one of the most important
fields because it consumes a large amount of electricity. About 15-22% of total
electricity production in the world is consumed in the lighting sector. Therefore,
understanding how to fabricate a white light-emitting diode is very necessary in order
to improve its practical application further. Basically, there are two methods of
fabrication for white light emitting diode, mixing of multiple LEDs and phosphor
converted white light emitting diode (pc-WLED). The luminous efficiency and
rendering index is influenced by the type of fabrication. In this chapter, the general
introduction of light emitting diode (LED), its working principle, characteristics of
light including CIE, color temperature and rendering index, the different modes of
fabrication for white light-emitting diodes, and their advantages and disadvantages
have been discussed.
Electronic and Piezoelectric Properties of Nonmetal Doped II-VI Monolayer Compounds
Page: 143-158 (16)
Author: Lalmuan Chhana, Zodinmawia, Ramesh Chandra Tiwari, Shivraj Gurung and Lalhriat Zuala*
DOI: 10.2174/9789815223101124030008
PDF Price: $30
Abstract
The enhancement of nano-system properties, particularly low dimensional
structures, is of great importance for future devices. Using spin-polarized Density
Functional Theory (DFT), electronic and piezoelectric properties of II-VI monolayer
(ZnO, ZnS, CdO and CdS) are studied. Variations of these properties are further
studied under substitutional doping of non-metal atoms (boron and carbon). Doping
with a B/C atom transforms all the monolayers into half-metallic ferromagnet, with
changes arising mainly from p-orbitals of the dopant (B/C) atom. Reduction of band
gap energy from its pristine structure is observed in all the doped cases. Observations
predicted that the B-doped ZnO and ZnS monolayer showed negative structural
stiffness and negative piezoelectric tensors, while C-doping remains stable with
enhanced elastic as well as piezoelectric properties of the monolayer.
A Theoretical Investigation on the New Quaternary MAX-phase Compounds (Zr1-xTix)3AlC2 (where x= 0-1)
Page: 159-201 (43)
Author: Habib Rached* and Ismail Ouadha
DOI: 10.2174/9789815223101124030009
PDF Price: $30
Abstract
The physical properties of the (Zr1-xTix)3AlC2
MAX-phase compounds have
been studied using the first-principle plane-wave method in the framework of the DFT
theory. The Perdew-Burke-Ernzerhof parametrization was chosen for the exchange
correlation (XC) energy. The equilibrium ground-state properties of the named
compounds were calculated and compared with the reported experimental and
theoretical data. The stability of our compounds has been analyzed. The electronic
structures were predicted, indicating all our compounds exhibit a metallic behavior.
The mechanical stability and elastic moduli were evaluated from the elastic constants.
The effect of temperature and pressure on Bulk modulus, Debye temperature and heat
capacity have been investigated and discussed in detail.
Surface Segregation in Pt3Nb and Pt3Ti using Density Functional Theory-based Methods
Page: 202-219 (18)
Author: Kingsley O. Obodo, Lalrin Kima, Adedapo S. Adeyinka and Dibya Prakash Rai*
DOI: 10.2174/9789815223101124030010
PDF Price: $30
Abstract
First-principles DFT calculations were used to investigate surface
segregation processes in ordered Pt3X (where X=Nb, Ti) alloys. Using pristine Pt (111)
surface as a reference, the effect of surface segregation on the adsorption energy of O2
atoms in Pt3X alloys was evaluated. Our results showed that surface segregation due to
direct exchange is only feasible for the Pt3Nb alloy (Esegr = - 0.3833 eV) but not for its
Ti analogue (Esegr = 0.516 eV). In contrast, for both Pt3X alloys, surface segregation due
to antisite migration and leading to the formation of a Pt-skin or overlayer, favouring
oxygen atom adsorption, an essential step in ORR, is possible. Interestingly, reverse
migration of X atoms from the bulk to replace Pt atoms on the surface is an
endothermic process and is thus very unlikely. Analysis of the surface segregation
energy for configurations involving a direct exchange of Pt atoms located beyond the
third layer in the slab model with Nb atoms at the surface indicates the formation of
pristine bulk like Pt (111) surface from Pt3Nb surface is unlikely. The energy of
adsorption for the O-atom on pristine Pt (111) surface shows that the presence of
minute quantities of dopant Nb atoms in the sub-surface layer could enhance its
suitability for ORR. Comparison of O-atom adsorption energy on the various surface
segregation models of Pt3X alloys to that of pristine Pt (111) surface shows that the
formations of a Pt-skin or overlayer on the Pt3Nb surface due to surface segregation
change the O-atom adsorption energy on this surface to 0.34 eV which is just 0.14 eV
higher than the optimal value of 0.20 eV. Our results also show that the binding of an
oxygen atom to the fcc Pt site in Pt3Ti is lower in energy compared to its binding on a
pristine Pt (111) surface. In comparison, the binding of an oxygen atom to the fcc Pt
site in Pt3Ti is of the same magnitude as that of the pristine Pt (111) surface.
Nanoparticles and Environmental Health
Page: 220-248 (29)
Author: Aparna Roy, Kumaresh Mandal, Shishir Tamang, Soni Subba, Saptaparni De, Divya Rai, Biswajit Roy and Rakesh Tamang*
DOI: 10.2174/9789815223101124030011
PDF Price: $30
Abstract
The size range of nanoparticles between 1-100nm is unique because of their
extremely small structure with a very high surface area to volume ratio. Besides
naturally produced nanoparticles, there is a huge worldwide demand for synthetic
nanoparticles. These synthetic nanoparticles are modified to some extent according to
the specific need. These manipulations at the nano-scale paved the way for a popular
branch of science called nanotechnology. However, with the massive use of
nanoparticle-based industrial products in our day-to-day lives, we knowingly or
unknowingly ignore their impact on the environment. The air, water, and soil quality
determines environmental health, which is reflected by a healthy ecosystem and its
biodiversity. The existing intricate interaction between humans and their surrounding
environment is important for maintaining a fine balance in the ecosystem. Any change
in this interaction may lead to adverse consequences. The nanoparticles released in the
environment cause a varying degree of effects on the ecosystem based on the type,
surface coating, and degree of its environmental transformation. Some nanoparticles
are harmful to the environment and some are beneficial. Some of the nanoparticles in
the environment get bioaccumulated in plants and animals, disturbing their growth and
productivity. Remediation by nanoparticles has been effective in removing some toxic
compounds from the environment, thereby providing a way to minimize pollution
efficiently. Thus, in this review, we have tried to present an overview of the sources,
fate, and effects of nanoparticles available in air, water, and soil. We strongly advocate
for the long-term assessment of nanoparticles, and the formulation of strict guidelines
for their usage by the concerned industries for better environmental health, and in turn
a healthy ecosystem.
Investigation for Optimum Site for Adsorption and Population Effect of Lithium on Silicene Monolayer
Page: 249-259 (11)
Author: Lalhumhima, Lalmuanchhana, Shivraj Gurung, Lalrinthara Pachuau, Lalmuanpuia Vanchhawng, Zodinmawia and Lalhriat Zuala*
DOI: 10.2174/9789815223101124030012
PDF Price: $30
Abstract
This investigation holds the search for optimum sites for Lithium on Silicene
Monolayer, by studying the adsorption energy on putting the Lithium atom on different
possible sites. The center of the hexagonal structure in silicene was found to be the
most favourable site. Using transition state search (TSS) the optimized stable state is
confirmed. A low Diffusion Energy Barrier (DEB) of 0.348 eV indicates that the
adsorption of Li over silicene can occur easily. Multiple adsorptions are considered, up
to 4 Li atoms upon silicene substrate. The metallic property of pristine silicene is
maintained throughout Li atom adsorption. Large adsorption energy in each of the
adsorption suggests that silicene may be promising for Li-based battery material.
Strategies for Synthesizing Metal Oxide Nanoparticles and the Challenges
Page: 260-282 (23)
Author: Harish Bishwakarma, Mukul Anand and Alok Kumar Das*
DOI: 10.2174/9789815223101124030013
PDF Price: $30
Abstract
The development of nanoscience and nanotechnology has improved our
quality of life. The new class of materials known as nanoparticles (NPs) contributes to
the development of nanotechnology. For the NPs, at least one dimension of particles
should be 1 to 100 nm. The synthesis approaches can modify NPs structure and size,
which is crucial in molecular biology, physics, chemistry, medicine, and material
science. The high surface area of NPs can be achieved via synthesis approaches,
providing increased value and imperative parameters like surface reactivity. Several
approaches to synthesizing NPs can be used, mainly categorized into two parts:
bottom-up and top-down. These two categories are classified based on the starting
materials used to synthesize the NPs. This review discussed the brief of synthesis
approaches and their utilization in the field of nanotechnology and nanoscience. The
novel approach to the synthesis of NPs i.e., the electrochemical discharge process, is
discussed in detail. The materials synthesis like ZnO, carbon, graphene, and other
metal oxide and their composite are discussed in tabular form. Finally, the challenges,
advantages, disadvantages, conclusions and NPs synthesis are discussed.
Heterogeneous Semiconductor Photocatalysis for Water Purification: Basic Mechanism and Advanced Strategies
Page: 283-311 (29)
Author: Naorem Premjit Singh* and Yengkhom Rangeela Devi
DOI: 10.2174/9789815223101124030014
PDF Price: $30
Abstract
Water is essential for all living things, whether it is human beings, animals
or plants. Around 70% of the total earth's surface is covered by water, however only a
small fraction of it (2.5%) is found as fresh water. On the other hand, due to
anthropogenic activities like industrialization, a huge increase in population, utilization
of toxic chemicals in agricultural activities etc., the available freshwater bodies have
been contaminated by various kinds of pollutants, including toxic chemicals released
mainly from industries like textile, which causes hazardous to both human being and
aquatic life. Therefore removal of these toxic chemicals before entering into fresh
water bodies is of great importance. Heterogeneous semiconductor photocatalysis is the
most effective green method in this regard because it enables to degrade the pollutants
into non hazardous products like CO2
and H2O without releasing any harmful residue.
Therefore, understanding the knowledge of photocatalysis mechanism is very
significant to enable further improvement. Hence, this chapter presents the basic
mechanism of photocatalysis, its drawbacks and the advanced strategies to improve the
catalytic efficiency. Finally some of the important factors that provide strong
influences on the catalytic activity also have been discussed.
Subject Index
Page: 312-317 (6)
Author: Dibya Prakash Rai, Kingsley O. Obodo and Jitendra Pal Singh
DOI: 10.2174/9789815223101124030015
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Introduction
The discovery of new materials and the manipulation of their exotic properties for device fabrication is crucial for advancing technology. Nanoscience, and the creation of nanomaterials have taken materials science and electronics to new heights for the benefit of mankind. Advanced Materials and Nanosystems: Theory and Experiment covers several topics of nanoscience research. The compiled chapters aim to update readers by highlighting modern developments in materials science theory and experiments. The significant role of new materials in future technology is also demonstrated. The book serves as a reference for curriculum development in technical institutions and research programs in the field of physics, chemistry and applied areas of science like materials science, chemical engineering and electronics. This part covers 11 topics in these areas: 1- Role of Plasmonic Metal-semiconductor Heterostructure in Photo Catalytic Hydrolysis and Degradation of Toxic Dyes 2 -BaZrO3-Based Ceramics and Ceramic Composites as Smart Materials for Advanced Applications 3 -A High-capacity Anode Material for Lithium-ion Batteries is Sili-graphene Type SiC3 4 -An Introduction to the Fabrication of White Light-emitting Diodes 5 -Electronic and Piezoelectric Properties of Nonmetal Doped II-VI Monolayer Compounds 6- A Theoretical Investigation on the New Quaternary MAX-phase Compounds 7- Surface Segregation in Pt 3 Nb and Pt 3 Ti using Density Functional-based Methods. 8- Nanoparticles and Environmental Health 9 -Investigation for Optimum site for adsorption and population effect of Lithium on Silicene Monolayer 10- Strategies for Synthesizing Metal Oxide Nanoparticles and the Challenges 11- Heterogeneous Semiconductor Photocatalysis for Water Purification: Basic Mechanism and Advanced Strategies