Date of Completion
1-20-2017
Embargo Period
1-20-2017
Keywords
SWSFETs; multi-channel FETs; ADC; VLSI; SRAM; QWell FET, SiGe
Major Advisor
Faquir Jain
Co-Major Advisor
John Chandy
Associate Advisor
John Ayers
Associate Advisor
Lei Wang
Associate Advisor
Evan Heller
Field of Study
Electrical Engineering
Open Access
Open Access
Abstract
This dissertation aims at developing circuit models for complementary (n- and p-channel) spatial wavefunction switched field-effect transistors (SWS-FETs). Unlike conventional FETs, SWS-FETs are comprised of two or more vertically stacked coupled quantum well or quantum dot channels, and the spatial location of carriers within these channels is used to encode the logic states (00), (01), (10) and (11). The development of SWS-FET logic gates and quaternary logics using sub 25 nm FETs is presented. In addition, simulation of compact 3-bit Analog-to-Digital Converters (ADCs) is presented. The accuracy of the SWS-FET circuits is verified by SWS-FET models in Cadence. The models are based on the integration of the Berkeley Short-channel IGFET Model (BSIM4.6) and the Analog Behavioral Model (ABM). The simulation results show using SWS-FETs reduce the number of transistors by 55% compared with CMOS counterpart.
Recommended Citation
Saman, Bander M, "Modeling of Multi-State Spatial Wavefunction Switched (SWS) FETs for Logic Gates and Memories" (2017). Doctoral Dissertations. 1329.
https://digitalcommons.lib.uconn.edu/dissertations/1329