Study of the Sensitive Region of a MOS Transistor to the Effects of Secondary Particles Arising from Ionizing Radiation

A. A. Glushko; Глушко А. А.; S. A. Morozov; Морозов С. А.; M. G. Chistyakov; Чистяков М. Г.

doi:10.31857/S0544126923700448

Study of the Sensitive Region of a MOS Transistor to the Effects of Secondary Particles Arising from Ionizing Radiation

Autores: Glushko A.¹, Morozov S.¹, Chistyakov M.²
Afiliações:
1. Scientific Research Institute for System Analysis, Russian Academy of Sciences
2. Bauman Moscow State Technical University
Edição: Volume 52, Nº 4 (2023)
Páginas: 282-289
Seção: НАДЕЖНОСТЬ
URL: https://journals.rcsi.science/0544-1269/article/view/138563
DOI: https://doi.org/10.31857/S0544126923700448
EDN: https://elibrary.ru/NXDJBB
ID: 138563

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Resumo

It was shown in [1, 2] that the dependence of the fault tolerance of a static RAM cell on the energy of secondary particles resulting from the action of a neutron flux does not take into account another signifi-cant factor—the part of the transistor in which these secondary particles are generated. In order to determine the area of the memory cell in which the impact of secondary particles can lead to a failure, the probability of a failure depending on the location of the occurrence of the secondary particle is studied. A method for ana-lyzing the accumulated charge is proposed for assessing the fault tolerance of a static random access memory cell depending on the place of occurrence of the secondary particle and the charge corresponding to the mar-gin of static noise immunity. The analysis is carried out based on the results of the instrumental-technological simulation of a single MOS transistor, which is part of a static RAM cell, and the integration of the obtained values of the current responses from the regions of the transistor.

Palavras-chave

TCAD, secondary particles, SRAM, MOS

Bibliografia

Глушко А.А., Чистяков М.Г., Кудинов И.В., Морозов С.А., Яшин Г.А., Амирханов А.В., Макарчук В.В., Зинченко Л.А. Методика сопряжения Монте-Карло моделирования радиационного транспорта и приборно-технологического моделирования для исследования одиночных сбоев / В сборнике докладов Международного форума “Микроэлектроника 2018” 4-й научной конференции “Электронная компонентная база и электронные модули”, Республика Крым, г. Алушта, 1–6 октября 2018 г., М., Изд-во “Техносфера”. С. 292–293.
Чистяков М.Г. Исследование и оптимизация по критерию сбоеустойчивости ячейки памяти для технологии КНИ КМОП 0.25 мкм при облучении быстрыми нейтронами В сборнике докладов Международного форума “Микроэлектроника 2017” 3‑й научной конференции “Электронная компонентная база и электронные модули”, Республика Крым, г. Алушта, 2–7 октября 2017 г., М., Изд-во “Техносфера”. С. 351–358.
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Dodd P.E., Sexton F.W. Critical Charge Concepts for CMOS SRAMs / IEEE Transactions on Nuclear Science. 1995. V. 42. № 6.
Seevinck E., List F.J., Lohstroh J. Static-Noise Margin Analysis of MOS SRAM Cells / IEEE J. Solid-State Circuits. 1987. V. Sc-22. № 5.