Title :
Charge-based modeling of channel material-engineered P-type double gate MOSFET
Author :
Kumari, Vandana ; Ilango, Aravindan ; Saxena, Manoj ; Gupta, Mridula
Author_Institution :
Dept. of Electron., Univ. of Delhi, New Delhi, India
Abstract :
A physics-based, charge-based model for P-type Gaussian doped DG MOSFET is presented in this work. The developed model is also applicable to the investigation of the impact of channel material on the performance of p-type DG MOSFET. The reliability issues of the p-type MOSFET have also been demonstrated using both developed analytical model and simulated results. The performance degradation due to unwanted interface trap density in both p-type and n-type DG MOSFET are also compared in this work. In addition to this, the impact of the straggle range of Gaussian doping on the performance of silicon (Si)- and germanium (Ge)-based DG MOSFET (in terms of threshold voltage, DIBL and Ion/Ioff ratio) has also been investigated and compared.
Keywords :
MOSFET; elemental semiconductors; germanium; semiconductor device models; semiconductor device reliability; semiconductor doping; silicon; DIBL; Ge; Si; channel material; germanium-based DG MOSFET; n-type DG MOSFET; p-type Gaussian doped DG MOSFET; physics-based charge-based model; reliability issues; silicon-based DG MOSFET; straggle range; threshold voltage; unwanted interface trap density; Analytical models; Doping; Leakage currents; Logic gates; MOSFET; Semiconductor device modeling; Silicon; ATLAS; Gaussian doping; germanium; interface charges; modeling;
Conference_Titel :
Emerging Electronics (ICEE), 2014 IEEE 2nd International Conference on
Print_ISBN :
978-1-4673-6527-7
DOI :
10.1109/ICEmElec.2014.7151141
