通过激光雷达探测大气生物气溶胶的可能性：基于波长的模拟研究

IF 1.1 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES Asian Journal of Atmospheric Environment Pub Date : 2024-07-05 DOI:10.1007/s44273-024-00035-y

Juseon Shin, Youngmin Noh

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引用次数: 0

摘要

本研究探讨了激光雷达技术在快速探测大气中气溶胶生物恐怖剂方面的潜力。它通过模拟不同波长（266、1064、1571 和 2000 nm）的消光系数和 Ångström 指数来评估应用情况，重点是区分生物气溶胶和典型大气颗粒。模拟分析评估了气溶胶分布的变化以及在清洁、正常和恶劣大气条件下相关消光系数和 Ångström 指数的变化。研究结果表明，1064 nm 波长可有效检测生物气溶胶的存在，1064 nm 和 1571 nm 波长的组合可为粒度区分提供最佳的 Ångström 指数。这种双波长方法是生物气溶胶检测的实用方法，对颗粒数量和大小的变化具有显著的灵敏度，这在生物威胁情况下至关重要。总之，这项研究为生物制剂检测系统选择激光雷达波长提供了指导。在为实际应用提供理论框架的同时，它还强调了进一步开展实验工作的必要性，以确认研究结果，并对技术进行微调，以用于现实世界的监测和威胁管理。这项研究有助于在生物恐怖威胁的背景下制定有效的监测战略。

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Possible detection of atmospheric bioaerosol via LiDAR: a wavelength-based simulation study

This study explores potential of LiDAR technology to rapidly detect aerosolized biological terror agents in the atmosphere. It assesses the application by simulating extinction coefficients and the Ångström exponent at various wavelengths (266, 1064, 1571, and 2000 nm), focusing on differentiating bioaerosols from typical atmospheric particles. The simulation analysis evaluates changes in aerosol distributions and related extinction coefficient and Ångström exponent shifts under clean, normal, and bad atmospheric conditions. The findings indicate that the 1064 nm wavelength effectively detects bioaerosol presence, with a combination of 1064 nm and 1571 nm providing optimal Ångström exponent use for particle size differentiation. This dual-wavelength approach is highlighted as a practical method for bioaerosol detection, showcasing a significant sensitivity to variations in particle quantity and size, which are critical in biological threat scenarios. In conclusion, the study offers guidance for selecting LiDAR wavelengths for biological agent detection systems. While providing a theoretical framework for practical applications, it also underlines the need for further experimental work to confirm findings and fine-tune technology for real-world monitoring and threat management. This research contributes to the development of effective monitoring strategies against the backdrop of biological terror threats.