激光诱导等离子体轰击细菌的理论模拟研究

Pub Date : 2024-10-01 DOI:10.1088/2058-6272/ad5adb
Junxiao WANG, Yan ZHANG, Wanfei ZHANG, Yong GUO, Lei ZHANG, Zefu YE, Zhujun ZHU, Wangbao YIN, Suotang JIA
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引用次数: 0

摘要

随着激光去污技术的飞速发展和人们对微生物危害认识的不断提高,采用理论模型模拟和评估激光诱导等离子体的去污过程变得至关重要。本研究采用二维轴对称流体动力学模型模拟等离子体轰击细菌的功率密度,并评估其去污效果。该模型考虑了蒸汽等离子体和背景气体分子的传输过程。基于等离子体中高速运动的粒子对细菌的破坏作用,我们研究了不同激光光斑尺寸、波长、平板倾斜角度和平板与目标间距等条件下的轰击功率密度。结果表明,轰击功率密度随着激光光斑尺寸和波长的减小而增大。例如,当平板与靶面平行且间距为 1 毫米时,当激光光斑尺寸从 0.8 毫米减小到 0.5 毫米时,轰击功率密度是原来的三倍;当波长从 1064 纳米减小到 266 纳米时,轰击功率密度是原来的四倍。值得注意的是,当板与目标平行且间距相对较近(0.5 毫米)时,倾斜 0° 时的轰击功率密度比倾斜 45° 时增加了七倍。这项模拟研究对于优化光学参数和设计使用激光诱导等离子体的净化装置的部件布局至关重要。减小激光光斑尺寸、波长、板-靶间距以及使板与靶平行,这些都有助于实现精确有效的去污。
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Theoretical simulation study of laser-induced plasma bombardment on bacteria
With the rapid advancement of laser decontamination technology and growing awareness of microbial hazards, it becomes crucial to employ theoretical model to simulate and evaluate decontamination processes by laser-induced plasma. This study employs a two-dimensional axisymmetric fluid dynamics model to simulate the power density of plasma bombardment on bacteria and access its decontamination effects. The model considers the transport processes of vapor plasma and background gas molecules. Based on the destructive impact of high-speed moving particles in the plasma on bacteria, we investigate the bombardment power density under various conditions, including different laser spot sizes, wavelengths, plate’s tilt angles, and plate-target spacing. The results reveal that the bombardment power density increases with a decrease in laser spot size and wavelength. For instance, when the plate is parallel to the target surface with a 1 mm spacing, the bombardment power density triples as the laser spot size decreases from 0.8 mm to 0.5 mm and quadruples as the wavelength decreases from 1064 nm to 266 nm. Notably, when the plate is parallel to the target with a relatively close spacing of 0.5 mm, the bombardment power density at 0° inclination increases sevenfold compared to 45°. This simulation study is essential for optimizing optical parameters and designing component layouts in decontamination devices using laser-induced plasma. The reduction of laser spot size, wavelength, plate-target spacing and aligning the plate parallel to the target, collectively contribute to achieving precise and effective decontamination.
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