Title :
Evidence for defect-generation-driven wear-out of breakdown conduction path in ultra thin oxides
Author :
Monsieur, F. ; Vincent, E. ; Ribes, G. ; Huard, V. ; Bruyère, S. ; Roy, D. ; Pananakakis, G. ; Ghibaudo, G.
fDate :
30 March-4 April 2003
Abstract :
This paper considers the physical mechanisms responsible for the progressive (i.e. smooth or noisy) breakdown manifestation commonly measured on ultra-thin oxides (Tox<25 Å). First, it is verified that the theory previously published is relevant by highlighting progressive behavior predicted on thicker oxides (50 Å). Second, the power dissipated is shown not to be correlated to the progressive behavior even if it influences the failure and its occurrence. Finally, the progression being gate voltage and temperature driven, it is shown that the defect generation probability drives the breakdown degradation after its creation. This is proven by measuring the influence on the progression of a bulk bias applied during the stress of a pMOS device in the inversion regime.
Keywords :
MOSFET; dielectric thin films; failure analysis; semiconductor device breakdown; semiconductor device reliability; 25 A; breakdown conduction path; breakdown degradation; breakdown manifestation; bulk bias; defect generation probability; defect-generation-driven wear-out; failure; inversion regime; pMOS device; physical mechanisms; power dissipation; runaway; ultra thin oxides; Breakdown voltage; Degradation; Electric breakdown; MOS devices; Research and development; Semiconductor device breakdown; Semiconductor device noise; Semiconductor optical amplifiers; Stress; Temperature distribution;
Conference_Titel :
Reliability Physics Symposium Proceedings, 2003. 41st Annual. 2003 IEEE International
Print_ISBN :
0-7803-7649-8
DOI :
10.1109/RELPHY.2003.1197785
