TY - GEN
T1 - Process-variation- and random-dopant-induced static noise margin fluctuation in nanoscale CMOS and FinFET SRAM cells
AU - Li, Tien Yeh
AU - Hwang, Chih Hong
AU - Li, Yi-Ming
PY - 2009
Y1 - 2009
N2 - In this study, a three-dimensional "atomistic" coupled device-circuit simulation approach is advanced to investigate the process-variation-effect (PVE) and random dopant fluctuation (RDF) induced characteristic fluctuations in planar metal-oxide-semiconductor field-effect-transistor (MOSFET) static random access memory (SRAM) from 65-nm to 16-nm gate length. Our preliminary results show that the RDF dominates the fluctuation of static noise margin (SNM). As the gate length of the planar MOSFETs scales from 65 nm to 16 nm, the normalized RDF-induced SNM fluctuation increases from 4% to 80%. To reduce the device variability induced fluctuation in circuit, a device with vertical-doping-profile and raised Vth is employed. The SNM is 3 times larger than the original 16-nm-gate SRAM. Moreover, the normalized RDF-induced SNM fluctuation is reduced by a factor of 2.67. Additionally, a 16-nm-gate silicon-on-insulator fin-type field-effect-transistor is used to further improve the SNM of SRAM. Due to the superior electrostatic integrity and larger effective device width than planar MOSFETs, the SNM of 16-nm-gate FinFET SRAM is six times larger than the original 16 nm SRAM with five times smaller SNM fluctuation. The study investigates the roll-off characteristics of SNM and provides an insight into design of fluctuation resistant nanoscale SRAM.
AB - In this study, a three-dimensional "atomistic" coupled device-circuit simulation approach is advanced to investigate the process-variation-effect (PVE) and random dopant fluctuation (RDF) induced characteristic fluctuations in planar metal-oxide-semiconductor field-effect-transistor (MOSFET) static random access memory (SRAM) from 65-nm to 16-nm gate length. Our preliminary results show that the RDF dominates the fluctuation of static noise margin (SNM). As the gate length of the planar MOSFETs scales from 65 nm to 16 nm, the normalized RDF-induced SNM fluctuation increases from 4% to 80%. To reduce the device variability induced fluctuation in circuit, a device with vertical-doping-profile and raised Vth is employed. The SNM is 3 times larger than the original 16-nm-gate SRAM. Moreover, the normalized RDF-induced SNM fluctuation is reduced by a factor of 2.67. Additionally, a 16-nm-gate silicon-on-insulator fin-type field-effect-transistor is used to further improve the SNM of SRAM. Due to the superior electrostatic integrity and larger effective device width than planar MOSFETs, the SNM of 16-nm-gate FinFET SRAM is six times larger than the original 16 nm SRAM with five times smaller SNM fluctuation. The study investigates the roll-off characteristics of SNM and provides an insight into design of fluctuation resistant nanoscale SRAM.
UR - http://www.scopus.com/inward/record.url?scp=70449511344&partnerID=8YFLogxK
U2 - 10.1109/ASQED.2009.5206305
DO - 10.1109/ASQED.2009.5206305
M3 - Conference contribution
AN - SCOPUS:70449511344
SN - 9781424449521
T3 - 2009 1st Asia Symposium on Quality Electronic Design, ASQED 2009
SP - 24
EP - 27
BT - 2009 1st Asia Symposium on Quality Electronic Design, ASQED 2009
T2 - 2009 1st Asia Symposium on Quality Electronic Design, ASQED 2009
Y2 - 15 July 2009 through 16 July 2009
ER -