A review of spectral broadening in laser atomic absorption spectroscopy

IF 3.1 2区化学 Q2 CHEMISTRY, ANALYTICAL

Journal of Analytical Atomic Spectrometry Pub Date : 2025-07-02 DOI:10.1039/D5JA00058K

Erfan Chenshen, Juntao Tan, Bin Wang, Erlong Jiang, Nan Zhao, Shaofeng Zheng, Zeren Luo, Jiaming Li and Qingmao Zhang

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Abstract

Laser atomic absorption spectroscopy (LAAS) has played a significant role in various fields such as nuclear forensics, chemical detection, medical diagnostics, environmental monitoring, and various industrial sectors, leveraging its unique advantages. However, spectral broadening phenomena significantly impact the accuracy and precision of LAAS measurements. This critical review examines spectral broadening and its implications for LAAS, incorporating recent advances in ultrafast diagnostics, extreme plasma conditions, and data-driven modeling. The convolution of various broadening mechanisms results in the final profile of spectral lines, among which Doppler, Stark, and pressure broadening are the primary sources in LAAS. Though spectral broadenings generally introduce measurement errors, they also provide crucial information about plasma characteristics. The review concludes with future perspectives, highlighting emerging technologies including artificial intelligence and novel suppression strategies that promise to enhance LAAS capabilities beyond current limitations.

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激光原子吸收光谱展宽研究进展

激光原子吸收光谱（LAAS）以其独特的优势，在核取证、化学检测、医学诊断、环境监测和各种工业领域发挥着重要作用。然而，光谱展宽现象严重影响LAAS测量的精度和精度。这篇重要的综述探讨了光谱展宽及其对LAAS的影响，结合了超快诊断、极端等离子体条件和数据驱动建模方面的最新进展。各种展宽机制的卷积形成了光谱线的最终轮廓，其中多普勒展宽、斯塔克展宽和压力展宽是LAAS的主要来源。虽然光谱加宽通常会引入测量误差，但它们也提供了关于等离子体特性的关键信息。报告最后对未来进行了展望，强调了包括人工智能和新型抑制策略在内的新兴技术，这些技术有望提高LAAS的能力，超越目前的限制。

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