Radiation and Oxide-Metal Interactions in MOS

Radiation and Oxide-Metal Interactions in MOS

Radiation stability of the MOS system is controlled by the oxide-silicon and oxide-metal barriers; oxide-metal interactions and certain dopants appear to affect the radiation sensitivity. It is shown that the OS system behaves differently from the MOS system. The effect of metals have been studied w...

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Veröffentlicht in:IEEE (Inst. Elec. Electron. Eng.), Trans. Nucl. Sci. NS-18: No. 6, 91-9(Dec 1971) Trans. Nucl. Sci. NS-18: No. 6, 91-9(Dec 1971), 1971-12, Vol.18 (6), p.91-98
1. Verfasser: Lindmayer, J.
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum
Chromium
Current measurement
Electrodes
Electrons
Electrostatics
Isothermal processes
Laboratories
MOS TRANSISTORS
N46300 -Instrumentation-Radiation Effects on Instrument Components, Instruments, or Electronic Systems
N74100 -Physics (Solid State)-Radiation Effects
RADIATION EFFECTS
SEMICONDUCTOR DEVICES/radiation effects on MOS
Semiconductor process modeling
Silicon
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Zusammenfassung:Radiation stability of the MOS system is controlled by the oxide-silicon and oxide-metal barriers; oxide-metal interactions and certain dopants appear to affect the radiation sensitivity. It is shown that the OS system behaves differently from the MOS system. The effect of metals have been studied with the use of aluminum, molybdenum and chromium. Chromium appears to be a desirable metal; when this electrode is used other factors also assume importance. The best results obtained with chromium gate p-enhancement transistors are: a shift of only 1.5 V (~1011 charges/cm2) with a Co-60 source depositing 2 x 107 rad(Si) or 1.5 MeV electrons depositing 1014 electrons/cm2. The change in surface mobility is small. Isothermal relaxation experiments show a wide range of activation energies, some of which are characteristic of the metal used. Studies related to the "photocurrent" flowing during irradiation appear to indicate that the prevailing model for radiation "damage" must be altered.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.1971.4326418