Compact modeling of non-classical MOSFETs for circuit simulation
This thesis documents the compact models developed for SOI/FinFET/SiNW MOSFETs as well as Schottky barrier and dopant-segregated Schottky MOSFETs. The Unified Regional Modeling approach is extended from bulk MOSFETs to SOI MOSFETs as well as the next generation FinFET/SiNW MOSFETs. SOI-spec...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2011
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/44550 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This thesis documents the compact models developed for SOI/FinFET/SiNW
MOSFETs as well as Schottky barrier and dopant-segregated Schottky MOSFETs.
The Unified Regional Modeling approach is extended from bulk MOSFETs to SOI
MOSFETs as well as the next generation FinFET/SiNW MOSFETs. SOI-specific
effects, such as floating-body and self-heating effects, are physically modeled using
both analytical and subcircuit approaches. The limitations of unipolar assumption are
explored through TCAD simulation and a novel symmetrical imref correction is
proposed to effectively remedy the unipolar assumption. A unified model for
FinFET/SiNW MOSFETs is formulated. The Gummel symmetry issue in three
terminal devices is essentially solved by the proposed effective drain-source voltage
expression. The unified model is validated extensively with experiment data and has
been coded in Verilog A for statistical and technology variation studies. A physicsbased
single piece compact model for undoped Schottky barrier SiNW MOSFETs is
formulated based on a quasi-2D surface potential solution and Miller-Good tunneling
model. Unique ambipolar behavior is excellently reproduced. A unique subcircuit
approach is proposed to physically model the dopant-segregation in Schottky SiNW
MOSFETs. The model can not only reproduce the unique convex curvature in Ids-Vds
characteristics, but also explain the process variations in particular the Schottky barrier
height variations. The research demonstrated the unique advantage of the Unified
Regional Modeling approach in modeling the next generation non-classical MOS
devices. |
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