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Effects of Moisture and Hydrogen Exposure on Radiation-Induced MOS Device Degradation and Its Implications for Long-Term Aging.

Authors :
Schwank, James R.
Shaneyfelt, Marty R.
Dasgupta, Aritra
Francis, S. A.
Zhou, Xing J.
Fleetwood, Daniel M.
Schrimpf, Ronald D.
Pantelides, Sokrates T.
Felix, James A.
Dodd, Paul E.
Ferlet-Cavrois, Veronique
Paillet, Philippe
Dalton, Scott M.
Swanson, Scot E.
Hash, Gerald L.
Thornberg, Steve M.
Hochrein, James M.
Lum, Gary K.
Source :
IEEE Transactions on Nuclear Science. Dec2008 Part 1 of 2, Vol. 55 Issue 6, p3206-3215. 10p. 1 Color Photograph, 2 Charts, 13 Graphs.
Publication Year :
2008

Abstract

Transistors and ICs built in several different captive and commercial facilities were exposed to moisture, irradiated, and annealed. The moisture exposures were performed using highly accelerated stress test (HAST) at 130degC and 85% relative humidity. Irradiation of n-channel transistors exposed to HAST followed by a long-term anneal resulted in some increase in interface-trap and oxide-trapped charge buildup. However, exposing p-channel transistors to HAST preirradiation resulted in extremely large and unexpected voltage shifts immediately following irradiation. They were observed for devices with either doped oxide or nitride final chip passivation. Because of this, nitride passivation may not be sufficient to prevent H2O from causing enhanced radiation-induced degradation over long time periods in some devices (e.g., commercial devices with nitride final chip passivation packaged in plastic packages). The smaller voltage shifts for the n-channel transistors may be related to the formation of phosphosilicate glass (PSG) overlying the sources and drains of the n-channel transistors impeding the diffusion of moisture to the gate oxides. It is shown that, the large radiation-induced voltage shifts for the p-channel transistors can lead to enhanced IC parametric degradation and functional failure at lower radiation levels. Large increases in radiation-induced field oxide leakage current were also observed for transistors exposed to HAST preirradiation. Transistors were also annealed (prior to irradiation) and irradiated in H2. Approximately the same level of radiation-induced degradation was observed for n- and p-channel transistors suggesting that the diffusion kinetics for H2 diffusion are considerably different than for H2O diffusion. These results raise the concern that exposure of devices to moisture or hydrogen can lead to long-term radiation-induced aging effects. [ABSTRACT FROM PUBLISHER]

Details

Language :
English
ISSN :
00189499
Volume :
55
Issue :
6
Database :
Academic Search Index
Journal :
IEEE Transactions on Nuclear Science
Publication Type :
Academic Journal
Accession number :
52037602
Full Text :
https://doi.org/10.1109/TNS.2008.2005676