Nanotechnology in Electronics

The book summarizes numerous research accomplishments in the area of nanotechnology for electronic applications. It covers materials such as semiconductors for nanoelectronics, graphene rubber- and non-rubber-based nanocomposites, nanowires, and carbon nanotubes. Applications are discussed in detail, including biosensors, optoelectronic devices, flexible electronics, nanoscale batteries, and nanogenerators.

Autorentext
Dr. Visakh P.M. is Assistant Professor at Tomsk State University, Tomsk, Russia. His research areas are polymer science, polymer nanocomposites, materials sciences, bio-nanocomposites, rubber-based nanocomposites, fire-retardant polymers and liquid crystalline polymers and silicon sensors. He published 17 original papers, three reviews and more than 30 book chapters. He is the editor of more than 25 books.

Dr. Artem Semkin is research scientist in the Department of Microwave and Quantum Radio Engineering at Tomsk State University, Tomsk, Russia. His areas of research are polymer science, optics, photonics, photopolymers, liquid crystals, and photopolymeric and liquid-crystalline compositions.

Dr. B. Raneesh is Assistant Professor in the Department of Physics, Catholicate College, Pathanamthitta, Kerala, India. His current research interests include nanomultiferroics, metal oxide thin films, plasma science and electron microscopy. He has published many research articles in peer-reviewed journals and also co-edited two books.

Dr. Sasa Lazovic is Assistant Professor at the Institute of Physics Belgrade, Serbia. He is head of the Laboratory for Biomimetics since 2016 and has been leading the Innovation Center of the Institute of Physics Belgrade from 2014-2018. He has published more than 20 papers in international journals on plasma physics, materials science, and biophysics.

Klappentext

Enables readers to understand and apply state-of-the-art concepts surrounding modern nanotechnology in electronics Nanotechnology in Electronics summarizes numerous research accomplishments in the field, covering novel materials for electronic applications (such as graphene, nanowires, and carbon nanotubes) and modern nanoelectronic devices (such as biosensors, optoelectronic devices, flexible electronics, nanoscale batteries, and nanogenerators) that are used in many different fields (such as sensor technology, energy generation, data storage and biomedicine). Edited by four highly qualified researchers and professionals in the field, other specific sample topics covered in Nanotechnology in Electronics include:

• Graphene-based nanoelectronics biosensors, including the history, properties, and fundamentals of graphene, plus fundamentals of graphene derivatives and the synthesis of graphene
• Zinc oxide piezoelectronic nanogenerators for low frequency applications, with an introduction to zinc oxide and zinc oxide piezoelectric nanogenerators
• Investigation of the hot junctionless mosfets, including an overview of the junctionless paradigm and a simulation framework of the hot carrier degradation
• Conductive nanomaterials for printed/flexible electronics application and metal oxide semiconductors for non-invasive diagnosis of breast cancer

• The fundamental aspects and applications of multiferroic-based spintronic devices and quartz tuning fork based nanosensors. Containing in-depth information on the topic and written intentionally to help with the practical application of concepts described within, Nanotechnology in Electronics is a must-have reference for materials scientists, electronics engineers, and engineering scientists who wish to understand and harness the state of the art in the field.

  Inhalt
  NANOTECHNOLOGY IN ELECTRONICS, MATERIALS PROPERTIES AND DEVICES: STATE OF ART AND CHALLENGES
  Graphene-Based Nano-Electronics Biosensors
  Zinc Oxide Piezoelectric Nanogenerators for Low-Frequency Applications
  Investigation of the Hot Carrier Induced Degradation in Nanoscale Functionless MOSFETs: A Reliability-Based Analysis
  Study of Electrostatic and Dispersion Forces in Nano-Electromechanical systems (NEMS)
  Nanomaterials for Wearable, Flexible and Stretchable Strain/Pressure Sensors
  Conductive Nanomaterials for Printed and Flexible Electronics Application
  Metal Oxide Semiconductors for Non-Invasive Diagnosis of Breast Cancer
  Down-Conversion Photoluminescence Properties of ZrO2:Ln3+ (Ln = Eu, Sm, Er, Tb, Ho, Tm, Pr, Gd, Dy) Films Formed by Plasma Electrolytic Oxidation
  Multiferroics for Spintronics Applications

  GRAPHENE-BASED NANOELECTRONICS BIOSENSORS
  Introduction on Graphene
  History of the Graphene
  Properties of Graphene
  Fundamentals of Graphene Derivatives
  Synthesis of Graphene
  Applications on Graphene-Based Biosensors

  ZINC OXIDE PIEZOELECTRONIC NANOGENERATORS FOR LOW FREQUENZY APPLICATIONS
  Introduction of Zinc Oxide
  Introduction on Zinc Oxide Piezoelectric Nanogenerators
  Zinc Oxide Piezoelectric Nanogenerators for Low Frequency Application
  Conclusion
  References

  INVESTIGATION OF THE HOT JUNCTIONLESS MOSFETS: A RELIABILITY BASED ANALYSIS CARRIER INDUCED DEGRADATION IN NANOSCALE
  Introduction
  Overview of the Junctionless Paradigm
  Simulation Framework of the Hot Carrier Degradation
  Creation Process of the Interface Traps
  Degradation of Performances Due to the Hot Carrier Effect
  Hot Carrier Degradation in Digital Applications
  Concluding Remarks
  References

  THE EFFECTS OF SYSTEM CONFIGURATION ON BEAM-BASED M/NEMS DEVICES
  Introduction
  Electrostatic Forces
  Fringing Field Effects
  Van der Waals Force
  Casimir Force
  Other Theories Related to the Casimir Force
  Freestanding Phenomenon
  Summary
  References

  NANOMATERIALS IN WEARABLE AND FLEXIBLE STRAIN/PRESSURE SENSORS
  Introduction
  Wearable Strain/Pressure Sensor
  Applications
  Conclusion and Outlook
  References

  CONDUCTIVE NANOMATERIALS FOR PRINTED AND FLEXIBLE ELECTRONICS APPLICATION

  METAL OXIDE SEMICONDUCTORS FOR NON-INVASIVE DIAGNOSIS OF BREAST CANCER

  DOWN-CONVERSION PHOTOLUMINESCENCE PROPERTIES OF ZrO2:Ln3+ (Ln = Eu, Sm, Er, Tb, Ho, Tm, Pr, Gd, Dy) FILMS FORMED BY PLASMA ELECTROLYTIC OXIDATION
  Introduction
  Experimental
  Results and Discussion
  CIE Chromaticity of ZrO2:Ln3+
  Conclusion

  MULTIFERROICS FOR SPINTRONICS APPLICATIONS
  Magnetoelectric Multiferroic Materials
  Spintronics
  Spintronics Devices
  Summary

  QUARTZ TUNING FORM BASED NANOSENSORS
  Introduction
  Chemical Sensors
  Quartz Tuning Forks (QTFs)
  Early QTF Development
  QTF as a Sensor
  Conclusions