Title :
A Compact Virtual-Source Model for Carbon Nanotube FETs in the Sub-10-nm Regime—Part I: Intrinsic Elements
Author :
Lee, C.-S. ; Pop, E. ; Franklin, A.D. ; Haensch, W. ; Wong, H.-S.P.
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
We present a data-calibrated compact model of carbon nanotube (CNT) FETs (CNTFETs) based on the virtual-source (VS) approach, describing the intrinsic current-voltage and charge-voltage characteristics. The features of the model include: 1) carrier VS velocity extracted from experimental devices with gate lengths down to 15 nm; 2) carrier effective mobility and velocity depending on the CNT diameter; 3) short channel effect such as inverse subthreshold slope degradation and drain-induced barrier lowering depending on the device dimensions; and 4) small-signal capacitances including the CNT quantum capacitance effect to account for the decreasing gate capacitance at high gate bias. The CNTFET model captures the dimensional scaling effects and is suitable for technology benchmarking and performance projection at the sub-10-nm technology nodes.
Keywords :
carbon nanotube field effect transistors; carrier mobility; CNTFET; carbon nanotube field effect transistor; carrier VS velocity; carrier effective mobility; charge-voltage characteristic; compact virtual-source model; dimensional scaling effect; drain-induced barrier lowering; intrinsic current-voltage characteristic; intrinsic element; inverse subthreshold slope degradation; quantum capacitance effect; short channel effect; small-signal capacitance; CNTFETs; Logic gates; Mathematical model; Numerical models; Numerical simulation; Quantum capacitance; CNTFET; Carbon nanotube (CNT); compact model; technology assessment; technology assessment.;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2015.2457453
