A Methodology to Estimate Single-Event Effects Induced by Low-Energy Protons

Eng Pub Date : 2024-02-19 DOI:10.3390/eng5010017

C. Marques, F. Wrobel, Y. Aguiar, A. Michez, J. Boch, Frédéric Saigné, R. García Alía

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Abstract

This work explains that the Coulomb elastic process on the nucleus is a major source of single-event effects (SEE) for protons within the energy range of 1–10 MeV. The infinite range of Coulomb interactions implies an exceptionally high recoil probability. This research seeks to extend the investigations under which the elastic process becomes significant in the energy deposition process by providing a simplified methodology to evaluate the elastic contribution impact on the reliability of electronics. The goal is to derive a method to provide a simple way to calculate and predict the SEE cross-section. At very low energy, we observe a significant increase in the proton differential cross-section. The use of a direct Monte Carlo approach would mainly trigger low energy recoiling ions, and a very long calculation time would be necessary to observe the tail of the spectrum. In this sense, this work provides a simple methodology to calculate the SEE cross-section. The single-event upset (SEU) cross-section results demonstrate a good agreement with the experimental data in terms of shape and order of magnitude for different technological nodes.

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低能质子诱发的单次事件效应估算方法

这项工作解释了原子核上的库仑弹性过程是 1-10 MeV 能量范围内质子单次事件效应（SEE）的主要来源。库仑相互作用的无限范围意味着极高的反冲概率。这项研究旨在通过提供一种简化方法来评估弹性作用对电子产品可靠性的影响，从而扩大对弹性过程在能量沉积过程中变得重要的调查范围。我们的目标是推导出一种方法，提供一种计算和预测 SEE 截面的简单方法。在极低能量下，我们观察到质子差分截面显著增加。使用直接蒙特卡罗方法主要会触发低能量的反冲离子，而且需要很长的计算时间才能观测到光谱的尾部。从这个意义上说，这项工作提供了一种计算 SEE 截面的简单方法。单次事件扰动（SEU）截面结果表明，在不同技术节点上，其形状和数量级与实验数据十分吻合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Eng

CiteScore

2.10

自引率

0.00%

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