Classical to Quantum Transport in Multi-Dimensional Field Effect Transistors

Ulteriori informazioni

This book covers the recent advancements in the transport models of various cutting edge technology semiconductor devices for sensing, circuits, in-memory or neuromorphic computing.

Sommario

Chapter 1- Introduction to Multi-Dimensional Field Effect Transistors (MuDFETs)
Mamataj Khatuna and Ekramul Kabir
Chapter 2- Introduction to Multi-Dimensional Field Effect Transistors (FETs)
Piyali Saha
Chapter 3- 2D Material Based Field Effect Transistors (FETs)
Piyali Saha, Soumya Sen, Prabhat Singh and Ashish Raman
Chapter 4- Emerging Transition Metal Dichalcogenides (TMDCs) in Semiconductor Design: A Path to Next-Generation Electronics
Malvika, Ashutosh Srivastava, Jagritee Talukdar, Rajan Singh, Prabhat Singh, Jami Venkata Suman
Chapter 5- From Classical to Quantum: Ballistic Transport in Nanosheet FETs
E.Rajalakshmi, N.B.Balamurugan, M.Hemalatha and M.Suguna
Chapter 6- Classical to Semi-classical Transport in Field Effect Transistors
Sharmistha Shee Kanrar, Shib Sankar Das and Subir Kumar Sarkar
Chapter 7- Scaling Capability Analysis of Junctionless Multi-Gate FETs
R. Ouchen, T. Berghout, F. Djeffal and H. Ferhati
Chapter 8- Nanosheet Transistors: A New Dimension in Charge Transport
Dr. Parul Devi
Chapter 9- Nanosheet Transistors: A New Dimension in Charge Transport
Vratika Verma, Teena Saini, Sakshi Saini and Jagram Meena
Chapter 10- The charge transport of the Breast Cancer Cells on Metal Strip-loaded Extended Source -TFET biosensor
Madhulika Verma and Sachin Agrawal
Chapter 11- Exploring Tunnel Field Effect Transistors (TFETs) as Label-Free Biosensors: Bridging Advances in Biosensing Technology
Basudha Dewan1 and Kamal Kishor Choure
Chapter 12- Field Effect Transistors in Gas Sensing: Advances in Detection and Analysis of Diverse Gases
Ankit Kumar Singh, Sanjeev Rai and Nirmal Roy
Chapter 13- High-Performance Silicon Nitride Waveguides: A Platform for Nonlinear and Quantum Photonics
Chandani Dubey, Prabhat Singh, Priya Kaushal, Dilip Singh, Malvika, Ashutosh Srivastava

Info autore

Naveen Kumar received his PhD from the Dr. B. R. Ambedkar National Institute of Technology, Jalandhar, India. Dr. Kumar is a postdoctoral research associate in DMG in the Electronic and Nanoscale Engineering Division, University of Glasgow. His research revolves around different semiconductor devices including ultra-scaled FETs, solar cells, photodiodes, HEMT, quantum dots, and their prospective applications. main areas of research interest include semiconductor device physics, MEMS/NEMS, and spintronics.
Prateek Kumar received his PhD from the University of Delhi, India. Dr. Kumar is a postdoctoral research associate and the for Electronic Devices and Integrated Circuits, Technical University of Dresden, Germany. His research includes next-generation SiGe HBTs, feedback FETs, and graphene-based transistors with special emphasis on quantum and semi-classical transport. His main areas of research interest include semiconductor device physics, MEMS/NEMS, and spintronics.
Ankit Dixit received his Ph.D. in Electronics and Communication Engineering from the Indian Institute of Information Technology, Design, and Manufacturing, Jabalpur, India. He carried out his research on III-V materials for the application of low-power devices and biosensor applications. Dr. Dixit is working as a research associate in the DeepNano Group, University of Glasgow, Scotland, where he is responsible for conducting research on nanoelectronics device simulations and variability analysis for novel devices.
Prabhat Singh received his PhD from the National Institute of Technology, Hamirpur, Himachal Pradesh, India. Dr. Singh is a postdoctoral research associate in the School of Electrical and Computer Science at IIT Bhubaneswar, Odisha. His research revolves around different semiconductor devices including cryogenic CMOS, ultra-scaled FETs, solar cells, quantum dots, and their prospective applications. His main areas of research interest include semiconductor device physics, solid-state devices, analog complementary metal oxide semiconductor (CMOS) integrated circuits, and nanoscale device design and simulation.