Title :
Collective-effect state variables for post-CMOS logic applications
Author :
Chen, A. ; Jacob, A.P. ; Sung, C.Y. ; Wang, K.L. ; Khitun, A. ; Porod, W.
Author_Institution :
Strategic Technol. Group, Adv. Micro Devices, Sunnyvale, CA, USA
Abstract :
Si CMOS represents a nearly optimal implementation of charge-based logic devices. To extend logic device performance significantly beyond CMOS, it may be necessary to explore collective-effect state variables. This paper analyzes logic devices based on several collective-effect state variables: collective spin polarization (ferromagnet), collective spin oscillation (spin wave), and correlated charge (exciton condensation in bi-layer structures). The benefits and challenges of these novel devices for VLSI applications are discussed.
Keywords :
CMOS logic circuits; VLSI; ferromagnetic materials; logic devices; spin waves; VLSI; charge-based logic devices; collective spin oscillation; collective spin polarization; collective-effect state variables; correlated charge; exciton condensation; ferromagnet; postCMOS logic applications; spin wave; CMOS logic circuits; Excitons; FETs; Logic devices; Magnetic materials; Nanoscale devices; Polarization; Switches; Switching circuits; Very large scale integration;
Conference_Titel :
VLSI Technology, 2009 Symposium on
Conference_Location :
Honolulu, HI
Print_ISBN :
978-1-4244-3308-7
