Optimal regime of the double-sided drift of lithium ions into silicon monocrystal

Physical Sciences and Technology Pub Date : 2023-06-01 DOI:10.26577/phst.2023.v10.i1.03

regime of the R.A. Muminov, double-sided drift N.M. Japashov, lithium ions Yo.K. Toshmurodov, Al-Farabi A.K. Saymbetov 1 NNLOT, R. A. M. K. National, Almaty N.M. Japashov, Yo. K. Toshmurodov, M. Nurgaliyev, N. B. K. e-mail, B. Zholamanov

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Abstract

In this work, we show a new method for obtaining silicon-lithium semiconductor structures using the bilateral drift of lithium particles into silicon mono-crystal in order to create nuclear radiation detectors with a wide bandgap. This method describes the simultaneous distribution of lithium ions on surfaces of cylindrical silicon crystals, which speeds up the process of obtaining the required detector structure. Here in this work, we aimed to identify the most optimal regimes of the electric field applied in the process of bilateral ion drift, as well as to investigate the effect of the thermal factors to create a drift of lithium ions. We can estimate these optimal regimes of voltage and temperature by making theoretical assumptions based on the numerical method for solving the Poisson continuity equation, the calculations of Pell and Louber. At the same time, simplifications were made to neglect the internal interaction of particles. The paper shows the results of modeling the process of bilateral drift under the influence of a stepwise increase in temperature and reverse voltage. This bilateral drift procedure facilitates the fabrication of silicon-lithium nuclear radiation detectors with large diameters and sensitive areas.

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锂离子双面漂移到硅单晶的最佳状态

在这项工作中，我们展示了一种利用锂粒子双边漂移到硅单晶中获得硅锂半导体结构的新方法，以创建具有宽带隙的核辐射探测器。该方法描述了锂离子在圆柱形硅晶体表面的同时分布，从而加快了获得所需探测器结构的过程。在这项工作中，我们的目标是确定在双边离子漂移过程中应用的最优电场制度，并研究热因素对锂离子漂移的影响。我们可以通过基于求解泊松连续性方程的数值方法，即Pell和Louber的计算，做出理论假设来估计这些电压和温度的最佳状态。同时，进行了简化，忽略了粒子的内部相互作用。本文给出了在温度和反向电压逐步升高的影响下双侧漂移过程的模拟结果。这种双边漂移过程有助于制造大直径和敏感区域的硅锂核辐射探测器。

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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Physical Sciences and Technology

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