2003
DOI: 10.1109/tns.2003.812930
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Radiation effects in SOI technologies

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Cited by 383 publications
(150 citation statements)
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References 82 publications
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“…That dependence was caused by different field distribution in the buried oxide for short and longchannel devices under the TG bias as was shown in [19]. For long gate, drain and source bias only enhance charge trapping in local areas around the source and drain, having little effect on the central area under the gate.…”
Section: Resultsmentioning
confidence: 81%
See 1 more Smart Citation
“…That dependence was caused by different field distribution in the buried oxide for short and longchannel devices under the TG bias as was shown in [19]. For long gate, drain and source bias only enhance charge trapping in local areas around the source and drain, having little effect on the central area under the gate.…”
Section: Resultsmentioning
confidence: 81%
“…Some benefits can be gained by careful transistor type and process parameters selection and suitable substrate biasing [19]. Prior theoretical conclusions on radiation hardness of SOI devices are difficult to draw, thus experiment needs to be carried out.…”
Section: Introductionmentioning
confidence: 99%
“…The bipolar amplification is a phenomenon specific to partially-depleted SOI devices and its basic mechanism was largely explained and simulated in previous works (Ferlet-Cavrois et 81 al., 2002;Ferlet-Cavrois et al, 2004;Schwank et al, 2003). Bipolar amplification can also occur in fully depleted devices, as those studied here.…”
Section: Bipolar Amplificationmentioning
confidence: 71%
“…These can result in shifts of the threshold voltage, increases in static current leakage, errors in bit reading, and, eventually, in complete circuit and/or system failure [1], [2]. Strategies for increasing the radiation resilience of electronic devices typically include improving oxide quality [4], adopting silicon-on-insulator technology [5], and/or using III-V transistors with no oxide layers [6]. Commercial microelectronic devices can often withstand TID exposure to about 1-100 krad(SiO 2 ), and radiation hardened devices typically can withstand doses well above 100 krad(SiO 2 ) [7].…”
Section: Total-ionizing-dose Effects On Thresholdmentioning
confidence: 99%