Title :
Enhancing p-channel InGaSb QW-FETs via Process-Induced Compressive Uniaxial Strain
Author :
Guo, Luke W. ; Xia, Li ; Bennett, Brian R. ; Boos, J. Brad ; Ancona, Mario G. ; del Alamo, Jesus A.
Author_Institution :
Microsyst. Technol. Labs., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
We study the effect of process-induced uniaxial stress on the performance of biaxially strained InGaSb p-channel quantum-well field-effect transistors (QW-FETs). Uniaxial stress is incorporated using a self-aligned nitride stressor. Compared with unstressed control devices, fabricated stressed devices with a gate length of Lg=0.30 μm showed an increase of more than 40% in the drain current at VGS-VT =-0.5 V and VDS = -2.0) V, an enhancement of more than 40% in the peak extrinsic transconductance at VDS = -2.0) V, and a reduction in the source and drain resistance of 25%. These figures suggest an enhancement of the intrinsic transconductance by as much as 60%. The improvement in device characteristics was also found to scale favorably with gate length. The results indicate that process-induced compressive uniaxial strain holds great promise for developing high-performance antimonide-based p-FETs.
Keywords :
field effect transistors; indium compounds; quantum well devices; stress analysis; stress-strain relations; InGaSb; QW-FET; antimonide-based p-FET; biaxially strained p-channel quantum-well field-effect transistor; drain resistance; intrinsic transconductance; peak extrinsic transconductance; process-induced compressive uniaxial strain; process-induced uniaxial stress effect; self-aligned nitride stressor; size 0.30 mum; source resistance; unstressed control device; voltage -0.5 V; voltage -2.0 V; Logic gates; Performance evaluation; Stress; Transconductance; Transistors; Uniaxial strain; Antimonide; InGaSb; QW-FETs; p-FET; stressed dielectric; uniaxial strain;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2014.2357429
