Dynamics of laser-ablated molybdenum plasma in vacuum: a novel spectral matching algorithm based on Saha–Boltzmann equilibrium for ne and Te determination in fusion wall diagnostics

IF 3.1 2区化学 Q2 CHEMISTRY, ANALYTICAL

Journal of Analytical Atomic Spectrometry Pub Date : 2025-07-08 DOI:10.1039/D5JA00157A

Xiaohan Hu, Huace Wu, Ding Wu, Xinyue Wang, Shiming Liu, Ke Xu, Ran Hai, Cong Li, Chunlei Feng and Hongbin Ding

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Abstract

Understanding the spatio-temporal evolution of plasma parameters is critical for advancing the accuracy of laser-induced breakdown spectroscopy (LIBS) in fusion reactor wall diagnostics. This study investigates the electron temperature (T_e) and electron density (n_e) dynamics of molybdenum (Mo) plasma—a key plasma-facing material in the Experimental Advanced Superconducting Tokamak (EAST)—generated by a nanosecond pulsed laser (6.0 GW cm⁻²) under vacuum (3 × 10⁻⁵ mbar). By integrating spatially resolved optical emission spectroscopy with fast ICCD imaging, we resolve the temporal scales of continuum radiation (5–60 ns), ionic lines (50–300 ns), and atomic lines (80–800 ns), revealing distinct spatial expansion profiles (up to 10 mm for neutral species). To overcome limitations of traditional Stark broadening methods (e.g., spectral overlap, missing electron collision parameters), we propose a spectral matching algorithm (SMA) based on Saha ionization equilibrium and Boltzmann distribution under local thermodynamic equilibrium (LTE). This method simplifies the calculation process of plasma parameters and achieves high correlation coefficients (>0.9) between simulated and experimental spectra. The results present a rapid cooling and decay behaviour of T_e (from 4.0 eV to 0.66 eV) and n_e (from 1.63 × 10²⁶ m⁻³ to 8.53 × 10²¹ m⁻³) within the time window of 50 ns to 310 ns in Mo plasma under present experimental conditions, driven by adiabatic expansion and three-body recombination. The spatial heterogeneity of T_e and n_e highlights non-equilibrium plasma behaviour. This work presents a method for plasma parameter (T_e and n_e) determination in calibration-free LIBS (CF-LIBS) applications for tokamak wall diagnostics, while simultaneously providing direct empirical validation data for laser ablation plasma dynamics simulations.

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真空中激光烧蚀钼等离子体动力学：一种基于Saha-Boltzmann平衡的新型光谱匹配算法，用于聚变壁诊断中ne和Te的测定

了解等离子体参数的时空演变对于提高激光诱导击穿光谱（LIBS）在聚变反应堆壁诊断中的准确性至关重要。本文研究了在真空（3 × 10−5 mbar）条件下，纳秒脉冲激光（6.0 GW cm−2）产生的钼（Mo）等离子体的电子温度（Te）和电子密度（ne）动力学。钼（Mo）等离子体是实验性先进超导托卡马克（EAST）的关键等离子体面材料。通过将空间分辨光学发射光谱与快速ICCD成像相结合，我们解析了连续辐射（5-60 ns）、离子线（50-300 ns）和原子线（80-800 ns）的时间尺度，揭示了不同的空间膨胀曲线（中性物质可达10 mm）。为了克服传统Stark展宽方法存在的光谱重叠、缺少电子碰撞参数等缺陷，提出了一种基于局域热力学平衡（LTE）下的Saha电离平衡和Boltzmann分布的光谱匹配算法（SMA）。该方法简化了等离子体参数的计算过程，实现了模拟光谱与实验光谱的高相关系数（>0.9）。结果表明，在本实验条件下，Mo等离子体中Te（从4.0 eV到0.66 eV）和ne（从1.63 × 1026 m−3到8.53 × 1021 m−3）在50 ns到310 ns的时间窗内，在绝热膨胀和三体复合的驱动下具有快速冷却和衰变行为。Te和ne的空间异质性突出了非平衡等离子体行为。本文提出了一种用于托卡马克壁诊断的免校准LIBS （CF-LIBS）应用中等离子体参数（Te和ne）的测定方法，同时为激光烧蚀等离子体动力学模拟提供了直接的经验验证数据。

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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