Title :
Monte Carlo simulation of deep-submicron SOI and conventional nMOSFET hot-electron-induced degradation
Author :
Higman, J.M. ; Orlowski, M.
Author_Institution :
Motorola Inc., Austin, TX, USA
Abstract :
A coupled Monte Carlo/drift diffusion simulation is applied to an n-channel conventional bulk MOSFET and two fully depleted n-channel SOI transitors. It is found that the SOI devices are more sensitive to trapped electron charge. The models, however predict far fewer high energy electrons (and fewer generated electron-hole pairs), the net result being that the SOI devices are more resistant to hot-electron-induced degradation. Furthermore, the p/sup +/-polysilicon gate SOI devices with lower channel doping are less prone to hot-electron-induced degradation than their n/sup +/gate counterparts. It is shown that the hot-electron flux incident at the SiO/sub 2/ is a function of both the lateral field and the vertical oxide field, if one takes into account barrier lowering and/or tunneling into the oxide.<>
Keywords :
Monte Carlo methods; carrier lifetime; electron traps; hot carriers; insulated gate field effect transistors; reliability; semiconductor device models; semiconductor-insulator boundaries; CMOS; Monte Carlo simulation; deep-submicron SOI; drift diffusion; fully depleted n-channel SOI transitors; hot-electron-induced degradation; n-channel conventional bulk MOSFET; p/sup +/-polysilicon gate SOI; trapped electron charge; CMOS technology; Degradation; Electrons; Interface states; MOSFET circuits; Research and development; Thermal conductivity; Thin film devices; Threshold voltage; Transconductance;
Conference_Titel :
Reliability Physics Symposium, 1993. 31st Annual Proceedings., International
Conference_Location :
Atlanta, GA, USA
Print_ISBN :
0-7803-0782-8
DOI :
10.1109/RELPHY.1993.283303
