Title :
Hydrodynamic transport parameters for holes in strained silicon
Author :
Bufler, F.M. ; Meinerzhagen, B.
Author_Institution :
Inst. fur Integrierte Syst., Eidgenossische Tech. Hochschule, Zurich, Switzerland
Abstract :
Drift velocities, carrier temperatures and energy relaxation times are computed by full-band Monte Carlo simulation along the <110> field direction at 300 K for holes in unstrained and [001]-strained Si grown on a Si/sub 0.7/Ge/sub 0.3/ substrate. The drift velocity as a function of the electric field is significantly enhanced under biaxial tensile strain, but is smaller than in the unstrained case when plotted versus the hole temperature because the holes are more easily heated under strain. The ohmic in-plane drift mobility and the transient velocity overshoot peak for a sudden application of a field of 100 kV/cm are enhanced by a factor of approximately three and two, respectively.
Keywords :
Monte Carlo methods; carrier lifetime; carrier relaxation time; elemental semiconductors; hole mobility; hot carriers; piezoresistance; silicon; 300 K; Si; Si/sub 0.7/Ge/sub 0.3/; Si/sub 0.7/Ge/sub 0.3/ substrate; [001]-strained Si; biaxial tensile strain; carrier temperatures; drift velocities; energy relaxation times; full-band Monte Carlo simulation; hole temperature; holes; hydrodynamic transport parameters; ohmic in-plane drift mobility; strained silicon; transient velocity overshoot peak; Capacitive sensors; Electron mobility; Germanium silicon alloys; Hydrodynamics; Lattices; MOSFET circuits; Phonons; Silicon germanium; Temperature; Tensile strain;
Conference_Titel :
Computational Electronics, 1998. IWCE-6. Extended Abstracts of 1998 Sixth International Workshop on
Conference_Location :
Osaka, Japan
Print_ISBN :
0-7803-4369-7
DOI :
10.1109/IWCE.1998.742756
