Preface
Page: i-i (1)
Author: Ekta Goel and Archana Pandey
DOI: 10.2174/9789815165647123010001
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Acknowledgements
Page: ii-ii (1)
Author: Ekta Goel and Archana Pandey
DOI: 10.2174/9789815165647123010002
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Role of Nanomaterials: In Novel Semiconductor Field Effect Transistors
Page: 1-24 (24)
Author: Chandra Keerthi Pothina, J. Lakshmi Prasanna and M. Ravi Kumar
DOI: 10.2174/9789815165647123010004
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Abstract
We are constantly looking to scale down the dimensions of transistors to
increase density in the same specific area and at the same time, having powerful
functions and increased performance. We have now reached the stage of submicron
technology where MOSFETs (metal oxide semiconductor field effect transistors) and
FinFETs (fin shaped field effect transistors) cannot be scaled down further. MOSFETs
replaced BJTs decades ago, but now transistors seem to have hit their end. While
semiconductor giants have a road map to produce 2 nm transistors, scaling down
further is next to impossible. Later, FinFETs were considered as their 3-dimensional
structure enabled greater density, greater computational power, and lower switching
times. But scaling down also means more thermal generation. Thermal effects, high
capacitances, and high fabrication costs deemed FinFETs not very suitable for scaling
down beyond 7nm. How can we enable transistors to scale down further and follow
Moore’s law? The next apparent step would be nanotechnology. While it could be a
revolution in VLSI it comes with its own cons and challenges. While there is a lot of
research going on regarding the same, this chapter will discuss types of nanomaterials
based on dimensions like 0D, 1D, 2D, and 3D, and their respective roles in
semiconductor FETs and why it is the next sensible step in the semiconductor industry.
Transition from Conventional FETs to Novel FETs, SOI, Double Gate, Triple Gate, and GAA FETS
Page: 25-46 (22)
Author: Jyoti Kandpal* and Ekta Goel
DOI: 10.2174/9789815165647123010005
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Abstract
Low-power application devices and inexpensive transistors are essential for
today's technological world. A 3 nm MOSFET nanoelectronic device has just been
created by researchers. Even though a MOSFET shrinks in size and uses less power,
SCEs still cause a few problems, leakage current, including Hot electron, Impact
Ionization, threshold voltage roll-off, Drain Induced Barrier Lowering (DIBL), and
others. One of the best-proposed structures to replace the MOSFET structure is the FIN
FET structure, which overcomes the limitations brought on by the CMOS transistor.
For low-power applications, the FIN FET structure is ideal. A FINFET structure
achieves an average subthreshold swing of 60 mv/decade at room temperature beyond
the boundaries of CMOS. This paper examines the performance of the many FINFET
architectures that have been proposed, including the double gate, tri-gate, and Gate All
Around FET.
FinFETs and their Applications
Page: 47-67 (21)
Author: Savitesh Madhulika Sharma* and Avtar Singh
DOI: 10.2174/9789815165647123010006
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Abstract
Researchers are motivated to develop novel electronic switches with
improved low power properties and reduced short channel effects due to the
downscaling of conventional MOSFETs (SCE). Using multi-gate FinFET technology
could improve control of the gate over the channel charge. We have discussed
FinFETs, or multigate transistors, in this chapter. The chapter will include the
classification and detailed physics inside the device. The Fabrication section will
explain the steps involved in manufacturing the device. The difficulties with FinFET
technologies have also been discussed in order to examine the research gap. The
performance improvement engineering techniques will give exposure to further
improvement techniques in the device. The circuit applications will address the various
analog/digital circuits based on FinFET.
Supply Voltage Scaling for Energy Efficient FinFET Logic
Page: 68-88 (21)
Author: Sarita Yadav*, Nitanshu Chauhan, Shobhit Tyagi, Arvind Sharma, Shashank Banchhor, Rajiv Joshi, Rajendra Pratap and Bulusu Anand
DOI: 10.2174/9789815165647123010007
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Abstract
A number of ultra-low power applications that don't need high performance
can gain power from running at the lowest supply voltage possible. Scaling the supply
voltage is a useful technique for cutting the energy needed by digital circuitry. Based
on Shannon's channel capacity theorem, the fundamental limit for supply voltage for
planar CMOS circuits has been determined to be 36 mV. FinFET devices fit ultra-low
voltage applications better than planar devices because of their nearly excellent sub-threshold properties. For the first time, the fundamental supply voltage limit for logic
circuits using FinFETs has been defined in this work. It is discovered that this
theoretical limit is considerably lower than the limit for planar CMOS devices. On this
fundamental limit, the impact of temperature variations and device design
characteristics is also investigated. Other logic gates, such as the NAND gate, are
included in the analysis. To determine this fundamental limit for a FinFET device, a
novel physics-based, semi-empirical current equation valid for supply voltage below
100 mV has been proposed. This is because the operation of a FinFET device in the
ultra-low voltage domain differs significantly from that of its planar counterpart. A
circuit designer values a current model like this because it makes calculations for back
of the envelope calculations simple. The proposed model is then used to study the logic
gates functioning in this regime.
Graphene FET for Microwave and Terahertz Applications
Page: 89-112 (24)
Author: Neetu Joshi*
DOI: 10.2174/9789815165647123010008
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Abstract
A graphene based FET can be used for a variety of applications. It can be
utilized in the fascinating field of nano-scale device electronics or microwave and
terahertz based guided wave components. In this chapter, a review of graphene field
effect transistors has been presented in RF and bio-sensor circuits. It begins with an
overview of the superior properties of graphene in graphene FETs, moving further to
the characterization and fabrication challenges, and thereafter, their application in
bioanalytical sensing and high frequency devices has been investigated. Graphene
material has potential advantages in the form of low losses and power dissipation due
to its high thermal, electrical conductivities and mobilities. It leads to better
performance and efficiency relative to its silicon counterparts in various applications. It
has some design and fabrication challenges owing to its high surface density and single
atomic thickness. It also shows limitations in terms of bandgap variation, high
fabrication costs and current saturation features.
Analysis of Negative to Positive Differential Conductance Transition in NCFET and Guidelines for Analog Circuit Designing
Page: 113-138 (26)
Author: Nitanshu Chauhan Chauhan*, Sudeb Dasgupta and Anand Bulusu
DOI: 10.2174/9789815165647123010009
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Abstract
In this chapter, we explained a detailed physical insight of Negative
Differential Resistance (NDR) to Positive Differential Resistance (PDR) transition in a
ferroelectric-based negative capacitance (NC) FET and its dependence on the device
terminal voltages. Using extensive well-calibrated TCAD simulations, we have
investigated this phenomenon on FDSOI NCFET. The NDR to PDR transition occurs
due to the Ferroelectric (FE) layer capacitance changes from a negative to a positive
state during channel pinch-off. This, in turn, results in a valley point in the output
characteristic (IDS-VDS) at which the output resistance is infinite. We also found that
we could alter the valley point location by modulating the vertical Electric field
through the FE layer in the channel pinch-off region using body bias (VBB). The
interface oxide charges also impacted the NDR to PDR transition, and a positive
interface charge resulted in a faster NDR to PDR transition. Further, we have utilized
the modulation in NDR to PDR transition due to VBack for designing a current mirror.
Results show that the output current (IOUT) variation due to VDS, reduces from ~8% to
~2% with VBack. We have also designed a single-stage common source (CS) amplifier
and provided design guidelines to achieve a higher gain in the NDR region. The results
obtained using a small-signal model of the FDSOI-NCFET demonstrate that ~25%
higher gain can be achieved with the discussed design guidelines in the NDR region
compared to the transition region of IDS-VDS. We have also explored the device scaling
effect on the amplifier gain and found that ~2.23x gain can be increased with a smaller
channel length and higher device width.
CMOS Compatible Single-Gate Single Electron Transistor (SG-SET) Based Hybrid SETMOS Logic
Page: 139-156 (18)
Author: Raj Shah* and Rasika Dhavse
DOI: 10.2174/9789815165647123010010
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Abstract
The continuous development of CMOS technology today beyond many
obstacles has been witnessed by all of us. After three decades of aggressive scaling to
ever-smaller dimensions, today, MOSFET gate lengths can be less than 22 nm. There
are many challenges and limitations at the device level. Short channel effects, such as
drain induced barrier lowering, Vth roll-off, gate induced drain leakage, static leakage,
punch through, and contact resistance, are among the major blockades for sub-22 nm
technology. Many physicists have explored this extremely small dimension device and
the effects of charge and energy quantization, and that emerged the concept of single
electron conduction. Single-electron devices were being seen as one of the finest
beyond-CMOS nanodevices reported by many researchers and ITRS. These devices
were facing many roadblocks due to their ultra-small dimensions, fabrication
viabilities, room temperature operation, CMOS compatible processes, and lack of
simulation methodology. Since the last decade, the evolution of advanced e-beam
lithography, Chemical-Mechanical polishing and deposition techniques has gained
many researchers’ attention, and the trend to explore these devices is going
continuously in an upward direction. Though it is difficult to replace CMOS
technology completely, the hybridization of these devices with CMOS is one of the
major interests shown by many research works.
Extensive Investigation on Even-Transistor-Configuration CMOS-based SRAM
Page: 157-176 (20)
Author: Dharmendra Singh Yadav*, Prabhat Singh, Vibhash Choudhary and Rakesh Murthy Gangadari
DOI: 10.2174/9789815165647123010011
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Abstract
Designing electronic devices with higher efficiency while using reduced
power is a problem in the field of electronics. Digital technology utilization is
increasing due to its higher speeds, lower power requirements, and stability. Accessing
data requires a lot of time, so a circuit is created that will be close to the CPU to
provide the information that is required. Cache memory is a type of SRAM-based
faster storing device. To enhance the performance of the SRAM cell, Read Delay (RD),
Write Delay (WD), read stability, write stability and power dissipation of the intended
circuit should all be carefully considered while designing an efficient SRAM cell.
Delay, power dissipation, and circuit stability all trade-off with one other. In this
chapter, we will look at delays, average power dissipation (APD), and stability using a
variety of cell ratios, pull-up ratios, and supply voltages, and compare how each of
these metrics has improved. As miniaturization of post CMOS technology, technology
nodes are getting smaller. Because of this, researchers have examined different
typologies, ranging from 6T SRAM to 12T SRAM (even-number transistor cell)
analysis. Better delays and an improved static noise margin are obtained by increasing
the number of transistors per cell, although power dissipation increases as a result. This
chapter covers the overall analysis for SRAM cells with 6T, 8T, 10T, and 12T
transistors that vary in CR and PR as well as voltage. The circuits are created for the
overall study using a 180nm technology file in the Cadence Virtuoso tool.
A Comparative Analysis and Ideas to Reduce Various Leakage Power in Modern VLSI
Page: 177-191 (15)
Author: J. Sravana*, A. Karthik and T. Dinesh
DOI: 10.2174/9789815165647123010012
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Abstract
In today's high-performance chips, comparative analysis and ideas for
reducing power consumption have become the dominant factor in overall power
consumption. This should reduce the power consumption of high-density chips, which
is so great that many new techniques have been developed in the proposal to design
low-power circuits and systems. Ultra-thin gate oxides, very low threshold voltages,
and short channels are hallmarks of nanoscale chips. Therefore, the most difficult
problem that arises in VLSI circuits and systems is power dissipation. This paper
provides an overview of sources of leakage currents in sub-micrometer CMOS gates
and techniques, limitations, analysis and ideas to reduce leakage currents [1]; an
overview of current circuit-level leakage currents [2] for various techniques; also
discusses an example of a 1-bit adiabatic ECRL adder which compares the power and
delay. This is one way of leakage minimization technique which is caused by switching
action. This simulation work is done in cadence tool using FINFET technology which
is a very fast-growing technology as compared to CMOS technology [3].
Subject Index
Page: 192-197 (6)
Author: Ekta Goel and Archana Pandey
DOI: 10.2174/9789815165647123010013
PDF Price: $15
Introduction
Nanoscale Field Effect Transistors: Emerging Applications is a comprehensive guide to understanding, simulating, and applying nanotechnology for design and development of specialized transistors. This book provides in-depth information on the modeling, simulation, characterization, and fabrication of semiconductor FET transistors. The book contents are structured into chapters that explain concepts with simple language and scientific references. The core of the book revolves around the fundamental physics that underlie the design of solid-state nanostructures and the optimization of these nanoscale devices for real-time applications. Readers will learn how to achieve superior performance in terms of reduced size and weight, enhanced subthreshold characteristics, improved switching efficiency, and minimal power consumption. Key Features: Quick summaries: Each chapter provides an introduction and summary to explain concepts in a concise manner. In-Depth Analysis: This book provides an extensive exploration of the theory and practice of nanoscale materials and devices, offering a detailed understanding of the technical aspects of Nano electronic FET transistors. Multidisciplinary Approach: It discusses various aspects of nanoscale materials and devices for applications such as quantum computation, biomedical applications, energy generation and storage, environmental protection, and more. It showcases how nanoscale FET devices are reshaping multiple industries. References: Chapters include references that encourage advanced readers to further explore key topics. Designed for a diverse audience, this book caters to students, academics and advanced readers interested in learning about Nano FET devices.