Title :
Quantum device-simulation with the density-gradient model on unstructured grids
Author :
Wettstein, Andreas ; Schenk, Andreas ; Fichtner, Wolfgang
Author_Institution :
Inst. fur Integrierte Syst., Swiss Federal Inst. of Technol., Zurich, Switzerland
fDate :
2/1/2001 12:00:00 AM
Abstract :
We describe an implementation of the density-gradient device equations which is simple and works in any dimension without imposing additional requirements on the mesh compared to classical simulations. It is therefore applicable to real-world device simulation with complex geometries. We use our implementation to determine the quantum mechanical effects for a MOS-diode, a MOSFET and a double-gated SOI MOSFET. The results are compared to those obtained by a 1D-Schrodinger-Poisson solver. We also investigate a simplified variant of the density-gradient term and show that, while it can reproduce terminal characteristics, it does not give the correct density distribution inside the device
Keywords :
MOSFET; semiconductor device models; semiconductor diodes; silicon-on-insulator; MOS-diode; MOSFET; complex geometries; density-gradient device equations; density-gradient model; double-gated SOI MOSFET; internal density distribution; quantum device-simulation; quantum mechanical effects; terminal characteristics; unstructured grids; Geometry; Hydrodynamics; MOSFET circuits; Maxwell equations; Multidimensional systems; Quantum mechanics; Schrodinger equation; Solid modeling; Threshold voltage; Tunneling;
Journal_Title :
Electron Devices, IEEE Transactions on
