Title :
Resonant gate tunneling current in double-gate SOI: a simulation study
Author :
Choi, Chang-Hoon ; Yu, Zhiping ; Dutton, Robert W.
Author_Institution :
Center for Integrated Syst., Stanford Univ., CA, USA
Abstract :
Gate tunneling current in fully depleted, double-gate (DG) silicon-on-insulator (SOI) MOSFETs is characterized based on quantum-mechanical principles. The gate tunneling current for symmetrical DG SOI with ground-plane (tox = 1.5 nm and TSI = 5 nm) is shown to be higher relative to single-gate (bulk) MOS structure. The tunneling is enhanced as the silicon layer becomes thinner since the thinner silicon layer acts a deep quantum well. The simulated IG-VG of DG SOI has negative differential resistance like that of the resonant tunnel diodes at the gate bias ∼ 1.4 V.
Keywords :
Green´s function methods; MOSFET; Schrodinger equation; negative resistance; resonant tunnelling; semiconductor device models; semiconductor quantum wells; silicon-on-insulator; Greens function simulator; Hartree self-consistency model; MOSFET; Schrodinger equation; Si; deep quantum well; discrete energy states; double-gate SOI; ground-plane; negative differential resistance; quantum-mechanical equation solver; resonant gate tunneling current; resonant tunnel diodes; symmetrical SOI; thinner silicon layer; Diodes; Electrons; Energy states; MOSFET circuits; Quantization; Quantum mechanics; Resonance; Resonant tunneling devices; Silicon on insulator technology; Threshold voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2003.920126
