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Computational Electronics is devoted to state of the art numerical
techniques and physical models used in the simulation of
semiconductor devices from a semi-classical perspective.
Computational electronics, as a part of the general Technology
Computer Aided Design (TCAD) field, has become increasingly
important as the cost of semiconductor manufacturing has grown
exponentially, with a concurrent need to reduce the time from
design to manufacture. The motivation for this volume is the need
within the modeling and simulation community for a comprehensive
text which spans basic drift-diffusion modeling, through energy
balance and hydrodynamic models, and finally particle based
simulation. One unique feature of this book is a specific focus on
numerical examples, particularly the use of commercially available
software in the TCAD community. The concept for this book
originated from a first year graduate course on computational
electronics, taught now for several years, in the Electrical
Engineering Department at Arizona State University. Numerous
exercises and projects were derived from this course and have been
included. The prerequisite knowledge is a fundamental understanding
of basic semiconductor physics, the physical models for various
device technologies such as pndiodes, bipolar junction transistors,
and field effect transistors.
It is generally acknowledged that modeling and simulation are
preferred alternatives to trial and error approaches to
semiconductor fabrication in the present environment, where the
cost of process runs and associated mask sets is increasing
exponentially with successive technology nodes. Hence, accurate
physical device simulation tools are essential to accurately
predict device and circuit performance. Accurate thermal modelling
and the design of microelectronic devices and thin film structures
at the micro- and nanoscales poses a challenge to electrical
engineers who are less familiar with the basic concepts and ideas
in sub-continuum heat transport. This book aims to bridge that gap.
Efficient heat removal methods are necessary to increase device
performance and device reliability. The authors provide readers
with a combination of nanoscale experimental techniques and
accurate modelling methods that must be employed in order to
determine a device's temperature profile.
It is generally acknowledged that modeling and simulation are
preferred alternatives to trial and error approaches to
semiconductor fabrication in the present environment, where the
cost of process runs and associated mask sets is increasing
exponentially with successive technology nodes. Hence, accurate
physical device simulation tools are essential to accurately
predict device and circuit performance. Accurate thermal modelling
and the design of microelectronic devices and thin film structures
at the micro- and nanoscales poses a challenge to electrical
engineers who are less familiar with the basic concepts and ideas
in sub-continuum heat transport. This book aims to bridge that gap.
Efficient heat removal methods are necessary to increase device
performance and device reliability. The authors provide readers
with a combination of nanoscale experimental techniques and
accurate modelling methods that must be employed in order to
determine a device's temperature profile.
This book surveys the advanced simulation methods needed for proper
modeling of state-of-the-art nanoscale devices. It systematically
describes theoretical approaches and the numerical solutions that
are used in explaining the operation of both power devices as well
as nano-scale devices. It clearly explains for what types of
devices a particular method is suitable, which is the most critical
point that a researcher faces and has to decide upon when modeling
semiconductor devices.
This book surveys the advanced simulation methods needed for proper
modeling of state-of-the-art nanoscale devices. It systematically
describes theoretical approaches and the numerical solutions that
are used in explaining the operation of both power devices as well
as nano-scale devices. It clearly explains for what types of
devices a particular method is suitable, which is the most critical
point that a researcher faces and has to decide upon when modeling
semiconductor devices.
Computational Electronics is devoted to state of the art numerical
techniques and physical models used in the simulation of
semiconductor devices from a semi-classical perspective.
Computational electronics, as a part of the general Technology
Computer Aided Design (TCAD) field, has become increasingly
important as the cost of semiconductor manufacturing has grown
exponentially, with a concurrent need to reduce the time from
design to manufacture. The motivation for this volume is the need
within the modeling and simulation community for a comprehensive
text which spans basic drift-diffusion modeling, through energy
balance and hydrodynamic models, and finally particle based
simulation. One unique feature of this book is a specific focus on
numerical examples, particularly the use of commercially available
software in the TCAD community. The concept for this book
originated from a first year graduate course on computational
electronics, taught now for several years, in the Electrical
Engineering Department at Arizona State University. Numerous
exercises and projects were derived from this course and have been
included. The prerequisite knowledge is a fundamental understanding
of basic semiconductor physics, the physical models for various
device technologies such as pndiodes, bipolar junction transistors,
and field effect transistors.
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