Title :
Negative bias temperature instability of p-channel transistors with diamond-like carbon liner having ultra-high compressive stress
Author :
Liu, Bin ; Tan, Kian-Ming ; Yang, Ming-Chu ; Yeo, Yee-Chia
Author_Institution :
Dept. of Electr. & Comput. Eng., Nat. Univ. of Singapore, Singapore, Singapore
Abstract :
The negative bias temperature instability (NBTI) characteristics of p-channel field-effect transistors with diamond-like carbon (DLC) liner stressor having ultra-high compressive stress (>5 GPa) are investigated for the first time. Ultra-Fast Measurement (UFM) was employed for NBTI study. Power law slopes ranging from ~0.057 to ~0.070 are reported in this work. P-FETs with higher channel strain show greater threshold voltage shift (DeltaVth) than those with lower or no channel strain under the same gate voltage VGS stress condition. DeltaVth recovery-behavior of highly strained devices suggests that both charge trapping and interface trap degradation are enhanced by strain. Despite this, strained p-FETs with recessed SiGe S/D and DLC stressors are projected to have a NBTI lifetime exceeding 10 years at VG = -1 V, showing no severe reliability issues.
Keywords :
compressive strength; diamond-like carbon; field effect transistors; interface states; semiconductor device measurement; semiconductor device reliability; thermal stability; C; FET reliability; NBTI; charge trapping; diamond-like carbon liner; highly strained device; interface trap degradation; negative bias temperature instability; p-channel field-effect transistor; ultra-fast measurement; ultra-high compressive stress; Capacitive sensors; Compressive stress; Degradation; Diamond-like carbon; FETs; Negative bias temperature instability; Niobium compounds; Silicon germanium; Threshold voltage; Titanium compounds; DLC; NBTI; UFM;
Conference_Titel :
Reliability Physics Symposium, 2009 IEEE International
Conference_Location :
Montreal, QC
Print_ISBN :
978-1-4244-2888-5
Electronic_ISBN :
1541-7026
DOI :
10.1109/IRPS.2009.5173394
