具有优先取向粒子的卷云光学模型在激光雷达中的应用

IF 0.9 Q4 OPTICS

Atmospheric and Oceanic Optics Pub Date : 2025-07-14 DOI:10.1134/S1024856025700113

A. V. Konoshonkin, N. V. Kustova, V. A. Shishko, D. N. Timofeev, A. E. Babinovich, Xuanhao Zhu, Zhenzhu Wang, Dong Liu, Yingjian Wang

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引用次数: 0

摘要

卷云在地球气候的形成中起着重要的作用，因此目前受到密切关注。它们主要是通过激光探测大气来研究的。激光探空数据的解释需要一个适当的卷云光学模型。然而，大多数现有的光学模型都是假设粒子的空间方向是随机的，根据最近的实验数据，这往往是不准确的。我们提出了一种考虑云内粒子优先水平方向的卷云光学模型。该模型包括理想的六角形板柱和准水平取向的空心柱；此外，它还包含六角形的板和柱、石柱和子弹、不规则形状的颗粒以及随机定向颗粒等颗粒的聚集体。该结果对于开发用于研究卷云的激光雷达数据解释算法至关重要。

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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Optical Model of Cirrus Clouds with Preferentially Oriented Particles for Lidar Applications

Cirrus clouds are currently under close attention since they play an important role in the formation of the Earth’s climate. They are mainly studied through laser sounding of the atmosphere. The interpretation of laser sounding data requires an adequate optical model of cirrus clouds. However, most existing optical models are developed assuming a random spatial orientation of particles, which, according to recent experimental data, is often inaccurate. We suggest an optical model of cirrus clouds which considers the preferential horizontal orientation of particles within a cloud. The model includes ideal hexagonal plates and columns and hollow columns as quasi-horizontally oriented particles; it additionally incorporates hexagonal plates and columns, droxtalls and bullets, irregularly shaped particles, and aggregates of such particles as randomly oriented particles. The results are crucial for developing lidar data interpretation algorithms for studying cirrus clouds.

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来源期刊

Atmospheric and Oceanic Optics OPTICS-

CiteScore

2.40

自引率

42.90%

发文量

期刊介绍： Atmospheric and Oceanic Optics is an international peer reviewed journal that presents experimental and theoretical articles relevant to a wide range of problems of atmospheric and oceanic optics, ecology, and climate. The journal coverage includes: scattering and transfer of optical waves, spectroscopy of atmospheric gases, turbulent and nonlinear optical phenomena, adaptive optics, remote (ground-based, airborne, and spaceborne) sensing of the atmosphere and the surface, methods for solving of inverse problems, new equipment for optical investigations, development of computer programs and databases for optical studies. Thematic issues are devoted to the studies of atmospheric ozone, adaptive, nonlinear, and coherent optics, regional climate and environmental monitoring, and other subjects.