|
Showing 1 - 13 of
13 matches in All Departments
This book covers various facets of nanomaterials and their
applications including low-dimensional materials along with
discussions on vitro cell imaging, bioanalyses, UV laser
applications of Scheelite-type nanomaterials, and Nano-sized
cyano-bridged metal organic framework including high spin
transition metal ions. It explains Transition Metal
Dichalcogenides, and Magnetic Tunnel Junction devices as an
alternative to CMOS devices. One of the main aims of this book is
to grow interest towards the atomistic simulation process and
characterization of these nanoscale devices. Details the recent
advances in the application of nanomaterials for nanoelectronics
devices, sensors and memories Describes the first-principle
approach towards ultra-sensitive electrically doped bio sensors
Discusses the application of nanomaterials in Spintronic Devices
specifically Magnetic Tunnel Junction device with new architectures
Covers nanomaterials in water purification and conducting polymer
nanocomposites in electrochemical supercapacitors Presents
theoretical background of next generation MRI contrast agent with
nano-sized cyanobridged metal organic framework including high spin
transition metal ions. This book is aimed at researchers and
graduate students in materials engineering and nanoelectronics.
How Can We Lower the Power Consumption of Gas Sensors? There is a
growing demand for low-power, high-density gas sensor arrays that
can overcome problems relative to high power consumption. Low power
consumption is a prerequisite for any type of sensor system to
operate at optimum efficiency. Focused on fabrication-friendly
microelectromechanical systems (MEMS) and other areas of sensor
technology, MEMS and Nanotechnology for Gas Sensors explores the
distinct advantages of using MEMS in low power consumption, and
provides extensive coverage of the MEMS/nanotechnology platform for
gas sensor applications. This book outlines the microfabrication
technology needed to fabricate a gas sensor on a MEMS platform. It
discusses semiconductors, graphene, nanocrystalline ZnO-based
microfabricated sensors, and nanostructures for volatile organic
compounds. It also includes performance parameters for the state of
the art of sensors, and the applications of MEMS and nanotechnology
in different areas relevant to the sensor domain. In addition, the
book includes: An introduction to MEMS for MEMS materials, and a
historical background of MEMS A concept for cleanroom technology
The substrate materials used for MEMS Two types of deposition
techniques, including chemical vapour deposition (CVD) The
properties and types of photoresists, and the photolithographic
processes Different micromachining techniques for the gas sensor
platform, and bulk and surface micromachining The design issues of
a microheater for MEMS-based sensors The synthesis technique of a
nanocrystalline metal oxide layer A detailed review about graphene;
its different deposition techniques; and its important electronic,
electrical, and mechanical properties with its application as a gas
sensor Low-cost, low-temperature synthesis techniques An
explanation of volatile organic compound (VOC) detection and how
relative humidity affects the sensing parameters MEMS and
Nanotechnology for Gas Sensors provides a broad overview of
current, emerging, and possible future MEMS applications. MEMS
technology can be applied in the automotive, consumer, industrial,
and biotechnology domains.
Responding to recent developments and a growing VLSI circuit
manufacturing market, Technology Computer Aided Design: Simulation
for VLSI MOSFET examines advanced MOSFET processes and devices
through TCAD numerical simulations. The book provides a balanced
summary of TCAD and MOSFET basic concepts, equations, physics, and
new technologies related to TCAD and MOSFET. A firm grasp of these
concepts allows for the design of better models, thus streamlining
the design process, saving time and money. This book places
emphasis on the importance of modeling and simulations of VLSI MOS
transistors and TCAD software. Providing background concepts
involved in the TCAD simulation of MOSFET devices, it presents
concepts in a simplified manner, frequently using comparisons to
everyday-life experiences. The book then explains concepts in
depth, with required mathematics and program code. This book also
details the classical semiconductor physics for understanding the
principle of operations for VLSI MOS transistors, illustrates
recent developments in the area of MOSFET and other electronic
devices, and analyzes the evolution of the role of modeling and
simulation of MOSFET. It also provides exposure to the two most
commercially popular TCAD simulation tools Silvaco and Sentaurus. *
Emphasizes the need for TCAD simulation to be included within VLSI
design flow for nano-scale integrated circuits * Introduces the
advantages of TCAD simulations for device and process technology
characterization * Presents the fundamental physics and mathematics
incorporated in the TCAD tools * Includes popular commercial TCAD
simulation tools (Silvaco and Sentaurus) * Provides
characterization of performances of VLSI MOSFETs through TCAD tools
* Offers familiarization to compact modeling for VLSI circuit
simulation R&D cost and time for electronic product development
is drastically reduced by taking advantage of TCAD tools, making it
indispensable for modern VLSI device technologies. They provide a
means to characterize the MOS transistors and improve the VLSI
circuit simulation procedure. The comprehensive information and
systematic approach to design, characterization, fabrication, and
computation of VLSI MOS transistor through TCAD tools presented in
this book provides a thorough foundation for the development of
models that simplify the design verification process and make it
cost effective.
Nano particles have created a high interest in recent years by
virtue of their unusual mechanical, electrical, optical and
magnetic properties and find wide applications in all fields of
engineering. This edited volume aims to present the latest trends
and updates in nanogenerators, thin film solar cells and green
synthesis of metallic nanoparticles with a focus on nanostructured
semiconductor devices. Exclusive chapter on electrical transport of
nanostructure explains device physics for material properties for
reduced dimensions. Additionally, the text describes the
functionality of metallic nanoparticles and their application in
molecular imaging and optical metamaterials. Piezoelectric
nanogenerators has been touched upon from the energy perspective as
well. Key Features: * Organized contents on Nanogenerators, VOC
sensing, nanoelectronics, and NEMS. * Discusses eco-friendly green
synthesis methods for metallic nanoparticles. * Touches upon low
power nano devices (e.g. nanogenerators) for energy harvesting with
quantum mechanical study. * Thin film/heterojunction based high
efficiency solar cell addressed aimed at reducing global energy
consumption.
Nano particles have created a high interest in recent years by
virtue of their unusual mechanical, electrical, optical and
magnetic properties and find wide applications in all fields of
engineering. This edited volume aims to present the latest trends
and updates in nanogenerators, thin film solar cells and green
synthesis of metallic nanoparticles with a focus on nanostructured
semiconductor devices. Exclusive chapter on electrical transport of
nanostructure explains device physics for material properties for
reduced dimensions. Additionally, the text describes the
functionality of metallic nanoparticles and their application in
molecular imaging and optical metamaterials. Piezoelectric
nanogenerators has been touched upon from the energy perspective as
well. Key Features: * Organized contents on Nanogenerators, VOC
sensing, nanoelectronics, and NEMS. * Discusses eco-friendly green
synthesis methods for metallic nanoparticles. * Touches upon low
power nano devices (e.g. nanogenerators) for energy harvesting with
quantum mechanical study. * Thin film/heterojunction based high
efficiency solar cell addressed aimed at reducing global energy
consumption.
Nanoelectronics: Physics, Materials and Devices addresses the
concepts involved in the exploration of research on nanoscale
electronics and photonic devices and their application in
next-generation integrated circuits (ICs). The book presents a
detailed discussion on the field of nanoscale electronic and
photonic devices, as well as the most recent techniques for the
modeling and simulation of these devices. It provides an in-depth
analysis of theoretical frameworks, the fundamental physics
underlying device operation, computational modeling, simulation
methods, and circuit applications of nanoscale devices. The purpose
of this book is to provide a desirable balance between basic
background and concepts to improve device performance. In this
book, both qualitative and quantitative approaches are considered
to analyze and explore the contributions made by various
researchers actively engaged in nanoscale device research. The
book's main motivation is to help solve the challenges of analyzing
and exploring the electrical behaviors of contemporary nanoscale
device technologies. It purposefully builds the principles of nano
electronic devices gradually, invigorating those of micro
electronic devices.
This book covers the basics of nanotechnology and provides a solid
understanding of the subject. Starting from a brush-up of the basic
quantum mechanics and materials science, the book helps to
gradually build up understanding of the various effects of quantum
confinement, optical-electronic properties of nanoparticles and
major nanomaterials. The book covers the various physical, chemical
and hybrid methods of nanomaterial synthesis and nanofabrication as
well as advanced characterization techniques. It includes chapters
on the various applications of nanoscience and nanotechnology. It
is written in a simple form, making it useful for students of
physical and material sciences.
This book teaches basic and advanced concepts, new methodologies
and recent developments in VLSI technology with a focus on low
power design. It provides insight on how to use Tanner Spice,
Cadence tools, Xilinx tools, VHDL programming and Synopsis to
design simple and complex circuits using latest state-of-the art
technologies. Emphasis is placed on fundamental transistor
circuit-level design concepts.
This book covers the basics of nanotechnology and provides a solid
understanding of the subject. Starting from a brush-up of the basic
quantum mechanics and materials science, the book helps to
gradually build up understanding of the various effects of quantum
confinement, optical-electronic properties of nanoparticles and
major nanomaterials. The book covers the various physical, chemical
and hybrid methods of nanomaterial synthesis and nanofabrication as
well as advanced characterization techniques. It includes chapters
on the various applications of nanoscience and nanotechnology. It
is written in a simple form, making it useful for students of
physical and material sciences.
How Can We Lower the Power Consumption of Gas Sensors? There is a
growing demand for low-power, high-density gas sensor arrays that
can overcome problems relative to high power consumption. Low power
consumption is a prerequisite for any type of sensor system to
operate at optimum efficiency. Focused on fabrication-friendly
microelectromechanical systems (MEMS) and other areas of sensor
technology, MEMS and Nanotechnology for Gas Sensors explores the
distinct advantages of using MEMS in low power consumption, and
provides extensive coverage of the MEMS/nanotechnology platform for
gas sensor applications. This book outlines the microfabrication
technology needed to fabricate a gas sensor on a MEMS platform. It
discusses semiconductors, graphene, nanocrystalline ZnO-based
microfabricated sensors, and nanostructures for volatile organic
compounds. It also includes performance parameters for the state of
the art of sensors, and the applications of MEMS and nanotechnology
in different areas relevant to the sensor domain. In addition, the
book includes: An introduction to MEMS for MEMS materials, and a
historical background of MEMS A concept for cleanroom technology
The substrate materials used for MEMS Two types of deposition
techniques, including chemical vapour deposition (CVD) The
properties and types of photoresists, and the photolithographic
processes Different micromachining techniques for the gas sensor
platform, and bulk and surface micromachining The design issues of
a microheater for MEMS-based sensors The synthesis technique of a
nanocrystalline metal oxide layer A detailed review about graphene;
its different deposition techniques; and its important electronic,
electrical, and mechanical properties with its application as a gas
sensor Low-cost, low-temperature synthesis techniques An
explanation of volatile organic compound (VOC) detection and how
relative humidity affects the sensing parameters MEMS and
Nanotechnology for Gas Sensors provides a broad overview of
current, emerging, and possible future MEMS applications. MEMS
technology can be applied in the automotive, consumer, industrial,
and biotechnology domains.
Responding to recent developments and a growing VLSI circuit
manufacturing market, Technology Computer Aided Design: Simulation
for VLSI MOSFET examines advanced MOSFET processes and devices
through TCAD numerical simulations. The book provides a balanced
summary of TCAD and MOSFET basic concepts, equations, physics, and
new technologies related to TCAD and MOSFET. A firm grasp of these
concepts allows for the design of better models, thus streamlining
the design process, saving time and money. This book places
emphasis on the importance of modeling and simulations of VLSI MOS
transistors and TCAD software. Providing background concepts
involved in the TCAD simulation of MOSFET devices, it presents
concepts in a simplified manner, frequently using comparisons to
everyday-life experiences. The book then explains concepts in
depth, with required mathematics and program code. This book also
details the classical semiconductor physics for understanding the
principle of operations for VLSI MOS transistors, illustrates
recent developments in the area of MOSFET and other electronic
devices, and analyzes the evolution of the role of modeling and
simulation of MOSFET. It also provides exposure to the two most
commercially popular TCAD simulation tools Silvaco and Sentaurus. *
Emphasizes the need for TCAD simulation to be included within VLSI
design flow for nano-scale integrated circuits * Introduces the
advantages of TCAD simulations for device and process technology
characterization * Presents the fundamental physics and mathematics
incorporated in the TCAD tools * Includes popular commercial TCAD
simulation tools (Silvaco and Sentaurus) * Provides
characterization of performances of VLSI MOSFETs through TCAD tools
* Offers familiarization to compact modeling for VLSI circuit
simulation R&D cost and time for electronic product development
is drastically reduced by taking advantage of TCAD tools, making it
indispensable for modern VLSI device technologies. They provide a
means to characterize the MOS transistors and improve the VLSI
circuit simulation procedure. The comprehensive information and
systematic approach to design, characterization, fabrication, and
computation of VLSI MOS transistor through TCAD tools presented in
this book provides a thorough foundation for the development of
models that simplify the design verification process and make it
cost effective.
|
|