DocumentCode
1459273
Title
Modeling Interconnects for Post-CMOS Devices and Comparison With Copper Interconnects
Author
Rakheja, Shaloo ; Naeemi, Azad
Author_Institution
Microelectron. Res. Center, Georgia Inst. of Technol., Atlanta, GA, USA
Volume
58
Issue
5
fYear
2011
fDate
5/1/2011 12:00:00 AM
Firstpage
1319
Lastpage
1328
Abstract
Power dissipation in charge-based technology is the biggest roadblock toward miniaturizing circuits. Quantum-mechanical tunneling and subthreshold leakage current will ultimately limit scaling of silicon field-effect transistors. To continue Moore´s law scaling, it is imperative that devices working with a state variable other than electron charge are sought for. Examples of alternate state variables include electron spins, pseudo-spins in graphene, direct and indirect excitons, plasmons, and phonons. At the same time, interconnection aspects of devices utilizing novel state variables must be considered early on. This paper provides a framework to quantify energy dissipation in interconnects for novel state variables. Models for energy per bit are then used along with previously derived models for delay of interconnects for novel state variables to compare performance and energy dissipation of novel interconnects with complementary metal-oxide-semiconductor (CMOS) interconnects. Comparison results provide important insights into material, device, and circuit implications of post-CMOS technologies.
Keywords
CMOS integrated circuits; copper; field effect transistors; integrated circuit interconnections; integrated circuit modelling; leakage currents; tunnelling; Cu; Moore law scaling; charge-based technology; complementary metal-oxide-semiconductor interconnects; copper interconnects; electron charge; electron spins; energy dissipation; graphene; interconnect modelling; post-CMOS devices; power dissipation; quantum-mechanical tunneling; silicon field-effect transistors; state variables; subthreshold leakage current; Current; Delay; Energy dissipation; Integrated circuit interconnections; Receivers; Resistance; Transmitters; Alternate state variable; excitons; interconnects; plasmonics; spintronics;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2011.2109004
Filename
5720298
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