Повышение радиационной устойчивости кремниевых монокристаллических эпитаксиальных слоев

Повышение радиационной устойчивости кремниевых монокристаллических эпитаксиальных слоев

The authors investigate the possibility of increasing the radiation resistance of silicon epitaxial layers by creating radiation defects sinks in the form of dislocation networks of the density of 109–1012 m–2. Such networks are created before the epitaxial layer is applied on the front sur...

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Bibliographic Details
Date:2014
Main Authors: Kurmashev, Sh. D., Kulinich, O. A., Brusenskaya, G. I., Verem’eva, A. V.
Format: Article
Language:Ukrainian
Published: PE "Politekhperiodika", Book and Journal Publishers 2014
Subjects:
эпитаксиальный кремний
дислокации
радиационные дефекты
сток дефектов
радиационная устойчивость
Online Access:https://www.tkea.com.ua/index.php/journal/article/view/TKEA2014.5-6.57
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Journal Title:Technology and design in electronic equipment

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Technology and design in electronic equipment
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Summary:The authors investigate the possibility of increasing the radiation resistance of silicon epitaxial layers by creating radiation defects sinks in the form of dislocation networks of the density of 109–1012 m–2. Such networks are created before the epitaxial layer is applied on the front surface of the silicon substrate by its preliminary oxidation and subsequent etching of the oxide layer. The substrates were silicon wafers KEF-4.5 and KDB-10 with a diameter of about 40 mm, grown by the Czochralski method. Irradiation of the samples was carried out using electron linear accelerator "Electronics" (ЭЛУ-4). Energy of the particles was 2,3–3,0 MeV, radiation dose 1015–1020 m–2, electron beam current 2 mA/m2. It is shown that in structures containing dislocation networks, irradiation results in reduction of the reverse currents by 5–8 times and of the density of defects by 5–10 times, while the mobility of the charge carriers is increased by 1,2 times. Wafer yield for operation under radiation exposure, when the semiconductor structures are formed in the optimal mode, is increased by 7–10% compared to the structures without dislocation networks. The results obtained can be used in manufacturing technology for radiation-resistant integrated circuits (bipolar, CMOS, BiCMOS, etc.).

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