SFX by Ex Libris Inc.

Title:	Current induced annealing and electrical characterization of single layer graphene grown by chemical vapor deposition for future interconnects in VLSI circuits
Source:	Applied Physics Letters [0003-6951] Prasad, Neetu yr:2014

Basic

Full text

Full text available via AIP Journals (American Institute of Physics)

Year:

Volume:

Issue:

Start Page:

Document delivery

Request document via Library/Bibliothek

Users interested in this article also expressed an interest in the following:
description	1.	Rakheja, S. "Evaluation of the Potential Performance of Graphene Nanoribbons as On-Chip Interconnects." Proceedings of the IEEE 101.7 (2013): 1740-1765.
description	2.	Kang, Chang G. "Effects of multi-layer graphene capping on Cu interconnects." Nanotechnology 24.11 (2013): 115707-.
description	3.	Naeemi, A. "Performance benchmarking for graphene nanoribbon, carbon nanotube, and Cu interconnects." 2008 International Interconnect Technology Conference 2008. 183-185.
description	4.	Kumar, V. "Performance and Energy-per-Bit Modeling of Multilayer Graphene Nanoribbon Conductors." IEEE Transactions on Electron Devices 59.10: 2753-2761.
description	5.	Sato, S. "Graphene for nanoelectronics." Japanese journal of applied physics 54.4 (2015): 40102-.
description	6.	Maffucci, A. "Number of Conducting Channels for Armchair and Zig-Zag Graphene Nanoribbon Interconnects." IEEE Transactions on Nanotechnology 12.5 (2013): 817-823.
description	7.	Chen, X. "Graphene Interconnect Lifetime: A Reliability Analysis." IEEE Electron Device Letters 33.11 (2012): 1604-6.
description	8.	Lalwani, G. "Fabrication and characterization of three-dimensional macroscopic all-carbon scaffolds." Carbon 53 (2012): 90-100.
description	9.	Dragoman, M. "Graphene for Microwaves." IEEE microwave magazine 11.7 (2010): 81-86.
description	10.	Rakheja, S. "Interconnects for Novel State Variables : Performance Modeling and Device and Circuit Implications." I.E.E.E. transactions on electron devices 57.10 (2010): 2711-2718.
description	11.	Rakheja, S. "Modeling Interconnects for Post-CMOS Devices and Comparison with Copper Interconnects." I.E.E.E. transactions on electron devices 58.5 (2011): 1319-28.
description	12.	Naeemi, J. "Compact Physics-Based Circuit Models for Graphene Nanoribbon Interconnects." IEEE transactions on electron devices 56.9 (2009): 1822-1833.
description	13.	Akinwande, D. "Two-dimensional flexible nanoelectronics." Nature communications 5.1 (2014): 5678-5678.
description	14.	Naeemi, A. "Conductance modeling for graphene nanoribbon (GNR) interconnects." IEEE electron device letters 28.5 (2007): 428-431.
description	15.	Kumar, V. "Analytical models for the frequency response of multi-layer graphene nanoribbon interconnects." 2012 IEEE International Symposium on Electromagnetic Compatibility 2012. 440-445.
description	16.	Gu, X. "Cu Single Damascene Integration of an Organic Nonporous Ultralow-k Fluorocarbon Dielectric Deposited by Microwave-Excited Plasma-Enhanced CVD." IEEE Transactions on Electron Devices 59.5 (2012): 1445-1453.
description	17.	Xu, Y. "Highly tunable spin-dependent electron transport through carbon atomic chains connecting two zigzag graphene nanoribbons." The Journal of chemical physics 137.10 (2012): 104107-.
description	18.	Soldano, C. "Carbon Nanotubes and Graphene Nanoribbons: Potentials for Nanoscale Electrical Interconnects." Electronics (Basel) 2.3 (2013): 280-314.
description	19.	Marin, Enrique G. "Analytical Gate Capacitance Modeling of III–V Nanowire Transistors." IEEE Transactions on Electron Devices 60.5 (2013): 1590-1599.
description	20.	Hashim, Daniel P. "Covalently bonded three-dimensional carbon nanotube solids via boron induced nanojunctions." Scientific Reports 2 (2012): 363-.