Study of the layer thickness of multilayer sample by the LIBS method based on ablation rate correction†

IF 3.1 2区 化学 Q2 CHEMISTRY, ANALYTICAL
Shiming Liu, Cong Li, Qi He, Huace Wu, Xiaohan Hu, Boliang Men, Ding Wu, Ran Hai, Xingwei Wu and Hongbin Ding
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Abstract

As a remote and in situ diagnostic technique for the first wall of tokamaks, laser-induced breakdown spectroscopy (LIBS) has shown promising potential for depth profile analysis of deposition layers on plasma-facing components (PFCs). However, due to the complexity of the interface of deposition layers and the limitations of laser profiles, achieving an accurate deposition layer thickness is often more difficult for an in situ LIBS system in tokamaks. In previous studies, a Laser Profile & Interface Roughness model (LPIR model), which considers the laser beam profile and interface roughness factors, has been developed to identify the interface of deposition layers. In this study, the effect of ablation rates from different materials in the deposited layers on the accuracy of their thickness has been investigated. The depth profiling of a Ni–Cu–Ni–Cu multilayer sample, which has a four-layer structure, has been carried out using the LIBS technique under different focusing conditions as well as various laser pulse energies, with the pressure maintained at 10−5 mbar. The LPIR model was used to reconstruct the depth distribution profile of the Ni–Cu–Ni–Cu multilayer sample and quantify the interfacial positions of the deposited layers. A layer thickness correction method for multilayer sample is proposed based on the dependence of the ablation rates of different layers on laser fluence. The correction ability has been evaluated based on the relative errors between the calculated and the scanning electron microscope (SEM) values for different layer thicknesses. The relative errors of the corrected layer thicknesses are all significantly improved, and the accuracy of the layer thicknesses has been substantially improved. The proposed method will not only help us better understand the LIBS depth profiling of multilayer samples under different laser fluence conditions, but it will also further improve the accuracy of the layer thickness analysis of multilayer samples. This result is of positive significance for the application of in situ LIBS diagnostics in plasma–wall interaction (PWI) studies.

Abstract Image

基于烧蚀率修正的 LIBS 法研究多层样品的层厚度
作为托卡马克第一壁的远程原位诊断技术,激光诱导击穿光谱(LIBS)在等离子体面元件(PFC)沉积层深度剖面分析方面显示出了巨大的潜力。然而,由于沉积层界面的复杂性和激光剖面的局限性,要在托卡马克中实现精确的沉积层厚度往往对原位激光诱导击穿光谱系统来说比较困难。在以前的工作中,已经开发了一种激光轮廓& 界面粗糙度模型(LPIR 模型),该模型考虑了激光束轮廓和界面粗糙度因素,用于识别沉积层的界面。在本研究中,研究了沉积层中不同材料的烧蚀率对厚度精度的影响。在不同的聚焦条件和不同的激光脉冲能量下,分别对具有四层结构的镍-铜-镍-铜多层样品进行了深度剖面分析,压力保持在 10-5 毫巴。利用 LPIR 模型重建镍-铜-镍-铜多层样品的深度分布曲线,并量化沉积层的界面位置。根据不同层的烧蚀率与激光通量的关系,提出了多层样品的层厚度校正方法。根据不同层厚度的计算值与扫描电子显微镜(SEM)值之间的相对误差,对校正能力进行了评估。校正后的层厚度相对误差均有明显改善,层厚度的精确度也得到了大幅提高。所提出的方法不仅能帮助我们更好地理解不同激光通量条件下多层样品的 LIBS 深度剖析,还能进一步提高多层样品的层厚分析精度。这一结果对于原位 LIBS 诊断在等离子体-壁相互作用(PWI)研究中的应用具有积极意义。
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来源期刊
CiteScore
6.20
自引率
26.50%
发文量
228
审稿时长
1.7 months
期刊介绍: Innovative research on the fundamental theory and application of spectrometric techniques.
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