Electron beam irradiation on novel coronavirus (COVID-19): A Monte-Carlo simulation.

Guobao Feng, Lu Liu, Wanzhao Cui, Fang Wang
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Abstract

The novel coronavirus pneumonia triggered by COVID-19 is now raging the whole world. As a rapid and reliable killing COVID-19 method in industry, electron beam irradiation can interact with virus molecules and destroy their activity. With the unexpected appearance and quickly spreading of the virus, it is urgently necessary to figure out the mechanism of electron beam irradiation on COVID-19. In this study, we establish a virus structure and molecule model based on the detected gene sequence of Wuhan patient, and calculate irradiated electron interaction with virus atoms via a Monte Carlo simulation that track each elastic and inelastic collision of all electrons. The characteristics of irradiation damage on COVID-19, atoms' ionizations and electron energy losses are calculated and analyzed with regions. We simulate the different situations of incident electron energy for evaluating the influence of incident energy on virus damage. It is found that under the major protecting of an envelope protein layer, the inner RNA suffers the minimal damage. The damage for a ∼100-nm-diameter virus molecule is not always enhanced by irradiation energy monotonicity, for COVID-19, the irradiation electron energy of the strongest energy loss damage is 2 keV.

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电子束辐照新型冠状病毒(新冠肺炎):蒙特-卡洛模拟。
新冠肺炎引发的新型冠状病毒肺炎正在全球肆虐。电子束辐照作为工业上快速可靠的杀死新冠肺炎的方法,可以与病毒分子相互作用并破坏其活性。随着病毒的突然出现和迅速传播,研究电子束辐照对新冠肺炎的作用机制迫在眉睫。在本研究中,我们基于武汉患者检测到的基因序列建立了一个病毒结构和分子模型,并通过蒙特卡罗模拟计算了辐照电子与病毒原子的相互作用,该模拟跟踪了所有电子的每次弹性和非弹性碰撞。计算并分析了新冠肺炎辐照损伤、原子电离和电子能量损失的区域特征。我们模拟了入射电子能量的不同情况,以评估入射能量对病毒损伤的影响。研究发现,在包膜蛋白层的主要保护下,内部RNA受到的损伤最小。对直径约为100-nm的病毒分子的损伤并不总是因辐射能量单调性而增强,对于新冠肺炎,最强能量损失损伤的辐射电子能量为2keV。
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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