Description
Carbon Nanotube and Graphene Nanoribbon Interconnects
Authors: Das Debaprasad, Rahaman Hafizur
Language: EnglishSubjects for Carbon Nanotube and Graphene Nanoribbon Interconnects:
Keywords
MWCNT Bundle; Allotropes of Carbon Nanomaterials; CNT Bundle; Applicability of CNT and GNR as Power Interconnects; Technology Node; CNT; SWCNT Bundle; GNR; CNT Interconnect; Growth of Carbon Nanotubes and Graphene Nanoribbon; Kinetic Inductance; Interconnect Delay; VLSI Circuit; Introduction to Allotropes of Carbon Nanomaterials; Modeling of Conducting Channels in CNT & GNR; Copper Interconnects; Power Integrity; RF Analysis in CNT and GNR Interconnects; Single MWCNT; Signal Integrity; RLC Parameter; Quantum Capacitance; Interconnect Length; Equivalent Circuit; Rolled Graphene Sheet; IR Drop; Te Ch; Gate Oxide Reliability; IR Drop Analysis; CNT Diameter; Aggressor Nets; Victim Net; Gate Oxide; Delay Uncertainty
Approximative price 87.11 €
In Print (Delivery period: 14 days).
Add to cart the book of Das Debaprasad, Rahaman HafizurPublication date: 11-2017
· 15.6x23.4 cm · Paperback
232.80 €
In Print (Delivery period: 15 days).
Add to cart the book of Das Debaprasad, Rahaman HafizurPublication date: 12-2014
· 15.6x23.4 cm · Hardback
Description
/li>Contents
/li>Readership
/li>Biography
/li>
An Alternative to Copper-Based Interconnect Technology
With an increase in demand for more circuit components on a single chip, there is a growing need for nanoelectronic devices and their interconnects (a physical connecting medium made of thin metal films between several electrical nodes in a semiconducting chip that transmit signals from one point to another without any distortion). Carbon Nanotube and Graphene Nanoribbon Interconnects explores two new important carbon nanomaterials, carbon nanotube (CNT) and graphene nanoribbon (GNR), and compares them with that of copper-based interconnects. These nanomaterials show almost 1,000 times more current-carrying capacity and significantly higher mean free path than copper. Due to their remarkable properties, CNT and GNR could soon replace traditional copper interconnects. Dedicated to proving their benefits, this book covers the basic theory of CNT and GNR, and provides a comprehensive analysis of the CNT- and GNR-based VLSI interconnects at nanometric dimensions.
Explore the Potential Applications of CNT and Graphene for VLSI Circuits
The book starts off with a brief introduction of carbon nanomaterials, discusses the latest research, and details the modeling and analysis of CNT and GNR interconnects. It also describes the electrical, thermal, and mechanical properties, and structural behavior of these materials. In addition, it chronicles the progression of these fundamental properties, explores possible engineering applications and growth technologies, and considers applications for CNT and GNR apart from their use in VLSI circuits.
Comprising eight chapters this text:
- Covers the basics of carbon nanotube and graphene nanoribbon
- Discusses the growth and characterization of carbon nanotube and graphene nanoribbon
- Presents the modeling of CNT and GNR as future VLSI interconnects
- Examines the applicability of CNT and GNR in terms of several analysis works
- Addresses the timing and frequency response of the CNT and GNR interconnects
- Explores the signal integrity analysis for CNT and GNR interconnects
- Models and analyzes the applicability of CNT and GNR as power interconnects
- Considers the future scope of CNT and GNR
Beneficial to VLSI designers working in this area, Carbon Nanotube and Graphene Nanoribbon Interconnects provides a complete understanding of carbon-based materials and interconnect technology, and equips the reader with sufficient knowledge about the future scope of research and development for this emerging topic.
Introduction to Allotropes of Carbon Nanomaterials. Growth of Carbon Nanotubes and Graphene Nanoribbon. Modeling of CNT and GNR Interconnects. Timing Analysis in CNT Interconnects. RF and Stability Analyses in CNT and GNR Interconnects. Signal Integrity in CNT and GNR Interconnects. Applicability of CNT and GNR as Power Interconnects. Future Applications of CNT and GNR. References. Index.
Dr. Debaprasad Das received a bachelor’s (honors) degree in physics in 1995, a bachelor’s degree in radio physics and electronics in 1998, a master’s degree in electronics and telecommunication engineering in 2006, and a PhD in engineering in 2013 from the Vidyasagar University, University of Calcutta, Jadavpur University, and Bengal Engineering and Science University, Shibpur, respectively. Presently, he is working as an associate professor and head in the Department of Electronics and Telecommunication Engineering, Assam University, Silchar, India. He has authored or coauthored several research papers in national and international journals and conferences, and authored four books.
Dr. Hafizur Rahaman