Title :
Modeling of Drain Electric Flux Passing Through the BOX Layer in SoI MOSFETs—Part II: Model Derivation and Validity Confirmation
Author :
Yamada, Tomoaki ; Hanajiri, Tatsuro ; Toyabe, Toru
Author_Institution :
Bio-Nano Electron. Res. Centre, Toyo Univ., Kawagoe, Japan
Abstract :
Increased drain-induced barrier lowering caused by drain electric flux (or field) passing through the buried-oxide (BOX) layer in silicon-on-insulator (SoI) MOSFETs has been reported as an inherent disadvantage of SoI technology. Part I of this paper discussed derivation of the relationships between coordinates in MOSFETs and potential/stream function in preparation for the modeling of electric flux using conformal mapping in subthreshold regions of ground plane SoI MOSFETs and the validity of the approach was checked via device simulation. Here, in Part II of this paper, we discussed the model´s derivation based on these relationships. The dependences of the flux amount on BOX thickness, BOX permittivity, SoI thickness, and gate length estimated using the model were also discussed in comparison with those estimated via device simulation.
Keywords :
MOSFET; buried layers; semiconductor device models; silicon-on-insulator; BOX layer; BOX permittivity; BOX thickness; Si; SoI technology; SoI thickness; buried-oxide layer; conformal mapping; device simulation; drain electric flux; drain-induced barrier lowering; gate length; ground plane SoI MOSFET; model derivation; potential-stream function; silicon-on-insulator MOSFET; validity confirmation; Capacitance; Electric potential; Logic gates; MOSFET; Permittivity; Semiconductor device modeling; Silicon-on-insulator; Buried oxide (BOX); conformal mapping; drain-induced barrier lowering (DIBL); electric field; electric flux; parasitic capacitance; relative permittivity; short channel effect; silicon-on-insulator (SoI) technology; silicon-on-sapphire (SoS);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2340900
