Investigation and optimization of electron gun beam, based on simulation and experimental results

Q4 Physics and Astronomy
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引用次数: 0

Abstract

Nowadays, by expanding the application of thin layers in industry and medical sciences, their fabrication methods have also received attention. One of those methods is the vaporizing material method with the help of an electron gun. The most important part in the electron gun is the electron optic, which is responsible for producing and accelerating electrons, so that it becomes possible to vaporize refractory materials in a shorter period of time by better modifying and controlling the electron beam (the shape and diameter of the electron beam) at the target location. The reduction and control of the beam diameter in this evaporation source depends on various parameters such as device geometry, magnetic field intensity, electric power, etc. Therefore, in this research, the effect of those parameters was investigated by conducting experiments and using finite element and modeling software. The simulation results revealed that the effect of the effective parameters on the beam diameter can be predicted to a good extent, so that the diameter of the electron beam decreases by changing the geometrical shape, size and displacement of the output beam components. Then, the new electron gun, compared to the existing prototype, is optimized by applying these changes in the construction of the device and conducting experiments, and its beam diameter is reduced by 40% to be more focused.
基于仿真和实验结果的电子束研究与优化
近年来,随着薄层材料在工业和医学上的广泛应用,薄层材料的制备方法也受到了人们的关注。其中一种方法是借助电子枪使材料汽化。电子枪中最重要的部分是电子光学,它负责产生和加速电子,通过在目标位置更好地修改和控制电子束(电子束的形状和直径),使耐火材料在更短的时间内汽化成为可能。该蒸发源中光束直径的减小和控制取决于器件几何形状、磁场强度、电功率等各种参数。因此,在本研究中,通过实验并使用有限元和建模软件来研究这些参数的影响。仿真结果表明,可以很好地预测有效参数对电子束直径的影响,从而通过改变输出光束组件的几何形状、尺寸和位移来减小电子束直径。然后,与现有原型相比,将这些变化应用于器件的构造和实验中,对新电子枪进行了优化,其光束直径减小了40%,更加聚焦。
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
Iranian Journal of Physics Research
Iranian Journal of Physics Research Physics and Astronomy-Physics and Astronomy (all)
CiteScore
0.20
自引率
0.00%
发文量
0
审稿时长
30 weeks
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