Predictive Simulation and Benchmarking of Si and Ge pMOS FinFETs for Future CMOS Technology

Predictive Simulation and Benchmarking of Si and Ge pMOS FinFETs for Future CMOS Technology

In this paper, we study and compare Si versus Ge pMOS FinFETs at advanced node dimensions using ensemble Monte Carlo simulations. It is found that due to large external resistance, lack of stressing methods, smaller bandgap, larger dielectric constant, and increased variability that in the absence o...

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Veröffentlicht in:IEEE transactions on electron devices 2014-07, Vol.61 (7), p.2271-2277
Hauptverfasser: Shifren, Lucian, Aitken, Robert, Brown, Andrew R., Chandra, Vikas, Binjie Cheng, Riddet, Craig, Alexander, Craig L., Cline, Brian, Millar, Campbell, Sinha, Saurabh, Yeric, Greg, Asenov, Asen
Format: Artikel
Sprache:eng
Schlagworte:
10-nm node
7-nm node
advanced node process
Channels
CMOS
CMOS variability
Computer simulation
Contact resistance
device physics
Dielectric constant
Electromagnetic compatibility
FinFET
FinFETs
Germanium
MOSFET
process technology
Resistance
SiGe
Silicon
Stress
Stressing
Substrates
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Zusammenfassung:In this paper, we study and compare Si versus Ge pMOS FinFETs at advanced node dimensions using ensemble Monte Carlo simulations. It is found that due to large external resistance, lack of stressing methods, smaller bandgap, larger dielectric constant, and increased variability that in the absence of major innovation, Ge is not an ideal candidate for channel replacement material of pMOS in future CMOS technology generation FinFETs. In order for Ge to compete with Si, it would at a minimum require a stressing mechanism and improved contact resistance, but leakage and variability would still be a concern for low-power applications.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2014.2323018