Title :
Modeling Advanced FET Technology in a Compact Model
Author :
Dunga, Mohan V. ; Lin, Chung-Hsun ; Xi, Xuemei ; Lu, Darsen D. ; Niknejad, Ali M. ; Hu, Chenming
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA
Abstract :
The need for meeting the expectations of continuing the enhancement of CMOS performance and density has inspired the introduction of new materials into the classical single-gate bulk MOSFET and the development of nonclassical multigate transistors at an accelerated rate. There is a strong need to understand and model the associated new physics and electrical behavior to ensure widespread very-large-scale-integration circuit applications of new technologies. This paper presents some of the efforts toward the modeling of new technologies for bulk MOSFETs and multigate transistors. A holistic model for mobility enhancement through process-induced stress and a dynamic behavior model for high-k transistors have been developed to capture some of the new effects and new materials in the bulk MOSFET. A new analytical model is also presented for the fundamentally new device structure-FinFET
Keywords :
MOSFET; VLSI; carrier mobility; semiconductor device models; FinFET; VLSI; advanced FET technology; analytical model; bulk MOSFET; compact model; dynamic behavior model; electrical behavior; high-k transistors; holistic model; mobility enhancement; multigate transistors; process-induced stress; Acceleration; CMOS technology; FETs; High K dielectric materials; MOSFET circuits; Physics; Semiconductor device modeling; Stress; Transistors; Very large scale integration; Berkeley short-channel insulated-gate FET model (BSIM); MOSFET; compact modeling; dielectrics; double-gate MOSFETs (DG-MOSFETs); high-; process-induced strain;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2005.881001
