Nanoelectronics

“Nanoelectronics” is an essential read for anyone interested in the cuttingedge world of molecular machines. This book explores the integration of nanoelectronics and molecular technology, providing a comprehensive guide to the transformative role they play in shaping modern science and technology. With practical insights, it offers an essential resource for professionals, students, enthusiasts, and hobbyists eager to understand the future of nanoengineering and molecular innovation.

Chapters Brief Overview:

1: Nanoelectronics: This chapter introduces the fundamental principles of nanoelectronics and its application in molecular machines.

2: Nanotechnology: Delves into the science of manipulating materials at the molecular level and its influence on nanoelectronics.

3: Molecularbeam epitaxy: Focuses on a key technique in fabricating nanostructures used in molecular electronics and nanotechnology.

4: JeanPierre Leburton: Highlights the work of this renowned scientist, contributing to the theoretical framework of nanoelectronics.

5: Nanochemistry: Discusses the role of chemistry in creating and modifying nanoscale devices for nanoelectronics.

6: Charles M. Lieber: Explores Lieber's groundbreaking contributions to the field, particularly in nanowire electronics.

7: Molecular nanotechnology: Introduces the integration of molecular science in the creation of nanoelectronics devices and systems.

8: History of nanotechnology: Provides a historical overview of nanotechnology's evolution, key discoveries, and milestones in the field.

9: Mark S. Lundstrom: Examines Lundstrom's contributions to understanding the quantum mechanics behind nanoelectronics.

10: Molecular electronics: Focuses on the design, operation, and application of molecular components in electronic systems.

11: Nanoengineering: This chapter looks at the engineering processes required to build nanoelectronic devices from molecular components.

12: Applications of nanotechnology: Explores the vast applications of nanotechnology in fields such as energy, medicine, and electronics.

13: Hybrid solar cell: Discusses the role of nanoelectronics in improving the efficiency and performance of solar cells.

14: Carbon nanotubes in interconnects: Highlights the potential of carbon nanotubes in replacing traditional materials in electronic interconnects.

15: Carbon nanotube fieldeffect transistor: Analyzes the use of carbon nanotubes in transistors, essential for miniaturized nanoelectronics.

16: Potential applications of carbon nanotubes: Investigates the versatile uses of carbon nanotubes in electronics and other industries.

17: Nanocircuitry: Explores the design and construction of nanoscale circuits and their applications in future technologies.

18: Nanowire: Discusses the role of nanowires in advancing nanoelectronics, offering unparalleled performance in miniaturized devices.

19: Silicon nanowire: Focuses on the potential of silicon nanowires for creating more efficient and powerful electronic components.

20: Multigate device: Explores the application of multigate devices in enhancing the performance and scalability of nanoelectronics.

21: Nanoelectromechanical systems: This chapter introduces the concept of nanoelectromechanical systems (NEMS), combining nanoelectronics with mechanical components for advanced applications.

“Nanoelectronics” provides an indepth understanding of the future of electronics, offering readers the knowledge to stay ahead of technological advances. With its detailed insights into the role of molecular machines in nanoelectronics, this book is invaluable for anyone seeking to understand and innovate in the world of nanoengineering.