Nanoelectronics : physics, technology and applications / Rutu Parekh, Rasika Dhavse.

Format:

Book

Author/Creator:

Parekh, Rutu, author.

Dhavse, Rasika, author.

Contributor:

Institute of Physics (Great Britain), publisher.

Series:

IOP (Series). Release 23.

IOP ebooks. 2023 collection.

[IOP release $release]

IOP ebooks. [2023 collection]

Language:

English

Subjects (All):

Nanoelectronics.

Physical Description:

1 online resource (various pagings) : illustrations (some color).

Place of Publication:

Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2023]

System Details:

Mode of access: World Wide Web.

System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.

Biography/History:

Dr. Rutu Parekh is an Associate Professor at DA-IICT, Gandhinagar, India. She received her M. Eng. in Electrical Engineering from Concordia University, Canada, and a PhD in Electrical Engineering (Nanoelectronics) from Universit�e de Sherbrooke, Canada. She was a postdoctoral fellow at Centre of Excellence in Nanoelectronics, IIT Bombay. She is also associated with The Inter-University Centre for Astronomy and Astrophysics, Pune, India, as a Visiting Associate. She holds more than 20 years of national and international experience in research and industry. She has published many articles in international journals and conference proceedings. Her research area includes high voltage ASIC design for space applications and design, modelling, and simulation of nanoelectronic circuits. Dr. Rasika Dhavse is an Associate Professor in the Department of Electronics Engineering at Sardar Vallabhbhai National Institute of Technology, Surat, India. She received her PhD in the field of nanocrystal-based flash memory devices in 2016. She has more than 25 years of academic experience. She has published many papers in international journals and conference proceedings, and is member of various reputed national and international professional bodies.

Summary:

This course text provides comprehensive coverage for fundamental and advanced courses in nanoelectronics. It provides insight into the future of electronics, emerging devices, logic and memory, sensors, systems architecture, nanofabrication, and the fundamental physics behind nanoelectronics. After reading the book, students will be able to understand the applications and design principles of nanodevices and nanosensors. The content is organised into nine chapters, each covering a specific area and written in accessible language. The topics covered include physical and technological limitations of nano CMOS devices, quantum physics, simulation and modelling, nanofabrication, emerging logic and memory devices and application areas including nanoarchitectures, sensors, and transducers. The book is a core text for senior undergraduate and postgraduate courses in nanoelectronics, and a valuable reference for researchers, engineers and specialists in fields including electronic devices, solid-state physics and nanotechnology.

Contents:

1. Physical and technological limitations of nano-CMOS devices to the end of the roadmap and beyond

1.1. MOSFETs and their scaling

1.2. Limitations and showstoppers arising from CMOS scaling, and technological options for MOSFET optimisation

2. Introduction and overview of nanoelectronics

2.1. Introduction

2.2. Market requirements for nanoelectronics

2.3. Nanofabrication

3. Introduction to the quantum theory of solids

3.1. Classical particles, classical waves and quantum particles

3.2. Quantum particles and principles of quantum mechanics

3.3. Quantum tunnelling

3.4. Quantum confinement

3.5. Schrodinger's wave equation

meaning, boundary conditions and applications

3.6. Significance of the band theory of solids

3.7. Factors affecting the energy band gap

3.8. Fermi statistics and electrical conduction in solids

4. Emerging research devices for nanocircuits

4.1. Channel-replacement devices

4.2. Graphene

4.3. Fullerenes and carbon nanotubes

4.4. Tunnel field-effect transistor

4.5. Nanowire field-effect transistors

4.6. P-type III-V channel-replacement devices

4.7. N-type Ge channel-replacement devices

4.8. Potential evaluation

extending MOSFETs to the end of the roadmap

4.9. Quantum confinement and associated devices

4.10. Quantum-mechanical tunnelling and Coulomb blockade in a single-electron transistor

4.11. Structure and working principle of single-electron transistors

4.12. Other quantum structures and their applications

4.13. Nanoelectromechanical systems

4.14. Atomic switches

4.15. Mott FETs

4.16. Negative-capacitance FETs

4.17. Alternative information-processing devices

5. Emerging memory devices

5.1. Memristors

5.2. Magnetoresistive effect for memory applications

5.3. Magnetoresistive RAM

5.4. Spin-transfer torque magnetic random access memory

5.5. All-spin logic

5.6. Phase-change memory

5.7. Resistive random access memory

5.8. Ferroelectric RAM

5.9. Mott memory

5.10. Carbon-based emerging memory devices

5.11. Molecular memory

5.12. Macromolecular memory

5.13. Racetrack memory

5.14. Comparison of memory types

6. Modelling and simulation

6.1. Technology modelling and simulation

6.2. Circuit simulators

6.3. Monte Carlo simulation

6.4. Microelectromechanical/nanoelectromechanical device simulators

6.5. System-level design

7. Nanofabrication

7.1. Microfabrication techniques

7.2. Limits of photolithography and advanced lithographic processes

7.3. Self-assembly processes

7.4. Nano measurement and characterisation tools

7.5. Thin-film technology and synthesis

7.6. Microelectromechanical, microoptoelectromechanical systems and nanoelectromechanical technologies

7.7. Process integration

8. Emerging nanoelectronic architectures

8.1. Storage class memory

8.2. Morphic computing : the architectures that can learn

9. Nanosensors and transducers

9.1. Introduction to sensors science and technology

9.2. Nanosensors and transducers in food industry, healthcare and defence

9.3. Metal nanoparticles and quantum-dots-based sensors

9.4. Carbon-nanotubes-based sensors

9.5. Electronic skin based on nanotechnology

9.6. Microelectromechanical/nanoelectromechanical sensors.

Notes:

"Version: 20231101"--Title page verso.

Includes bibliographical references.

Title from PDF title page (viewed on January 4, 2024).

Other Format:

Print version:

ISBN:

9780750348119

9780750348102

OCLC:

1416752870

Access Restriction:

Restricted for use by site license.