不同相对湿度下非球形海盐气溶胶颗粒的光散射特性研究

Remote. Sens. Pub Date : 2024-02-22 DOI:10.3390/rs16050770
Wentao Lian, Congming Dai, Shunping Chen, Yuxuan Zhang, Fan Wu, Cong Zhang, Chen Wang, Heli Wei
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引用次数: 0

摘要

在海洋环境中,海盐气溶胶颗粒从干燥时的立方体或长方体形状转变为不同湿度下的各种非球形形状,如椭圆体和圆柱体。复杂的湿度条件和颗粒形态给模拟非球形海盐气溶胶的光学散射特性带来了挑战。本研究针对真实环境场景,采用随机定向 T 矩阵计算方法,计算了海盐气溶胶在三种相对湿度条件(50%、80% 和 95%)和三种颗粒形态(球形、圆柱形和切比雪夫颗粒形状)下波长为 1.06 μm 的光散射和偏振特性。结果显示如下:(1) 就光学散射特性而言,在相同湿度条件下,颗粒的非球形度越大,非球形模型与球形模型之间的偏差就越大。对于球形和圆柱形海盐气溶胶,消光系数误差主要在 10%-30%之间,最大可达 120%;不对称系数误差主要在 3%-25%之间,最大可达 75%;正向散射相位函数误差主要在 10%-60%之间,最大可达 180%。与等效球形模型相比,切比雪夫颗粒状海盐气溶胶的光学散射特性偏差较小,一般在 5-25% 的范围内。在不同湿度条件下,各种非球形模型的海盐气溶胶粒子的散射特性参数与相对湿度呈正相关。当相对湿度低于 70% 时,不同形状的海盐气溶胶的光学散射特性受相对湿度的影响较小。相对湿度超过 70% 时,不同形状的海盐气溶胶的光学散射特性对相对湿度的变化更加敏感。(2)在偏振特性方面,湿度越大,对偏振特性的影响越明显,随着湿度的增加,非球形度越高的海盐气溶胶的偏振特性变化越复杂。非球形模型的形状差异主要影响极化特性的数值。在相同的湿度条件下,球形气溶胶的偏振特性与其他模型有显著差异。从气溶胶的去极化率来看,在不同的相对湿度条件下,圆柱形海盐气溶胶的去极化率最高,球形次之,切比雪夫形最小。相对湿度对去极化率的影响随散射角的变化而变化。相对湿度越高,去极化比随散射角的变化越复杂,曲线的振荡越明显,而非球形的形状越小,湿度引起的去极化比曲线的振荡越强烈。总之,本研究计算了不同相对湿度和形状下海盐气溶胶颗粒的光学散射和偏振特性,对实际海洋场景中 1.06 μm 激光工程和大气辐射传输等应用具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation of Light-Scattering Properties of Non-Spherical Sea Salt Aerosol Particles at Varying Levels of Relative Humidity
In the marine environment, sea salt aerosol particles transition from cubic or rectangular shapes when dry to various non-spherical shapes like ellipsoids and cylinders under different humidities. The complex humidity conditions and particle morphologies pose challenges to simulating the optical scattering properties of non-spherical sea salt aerosols. This study, addressing real environmental scenarios, employs the randomly oriented T-matrix computational method to calculate the optical scattering and polarization characteristics of sea salt aerosols at a wavelength of 1.06 μm under three relative humidity conditions (50%, 80%, and 95%) and three particle morphologies (spheroid, circular cylinder, and Chebyshev particle shapes). The results show the following: (1) In terms of optical scattering properties, the greater the non-sphericity of particles under the same humidity conditions, the larger the deviation between non-spherical and spherical models. For spheroid and circular cylinder sea salt aerosols, the error in the extinction efficiency factor mainly lies within 10–30%, reaching up to 120%; the error in the asymmetry factor is primarily between 3 and 25%, with a maximum of 75%, and the error in the forward-scattering phase function is mainly within 10–60%, reaching up to 180%. Chebyshev particle-shaped sea salt aerosols exhibit smaller deviations in optical scattering properties compared to equivalent spherical models, generally within the 5–25% range. Under different humidity conditions, the scattering characteristic parameters of sea salt aerosol particles for various non-spherical models show a positive correlation with relative humidity. When relative humidity is below 70%, the optical scattering properties of differently shaped sea salt aerosols are less affected by relative humidity. Above 70% relative humidity, the optical scattering properties of sea salt aerosols of different shapes become more sensitive to changes in relative humidity. (2) Regarding polarization properties, the greater the humidity, the more significant the impact on polarization properties, and as humidity increases, sea salt aerosols with higher non-sphericity exhibit more complex changes in polarization characteristics. The differences in shapes of non-spherical models mainly affect the numerical values of polarization properties. Under the same humidity conditions, spheroid polarization characteristics are significantly different from other models. In terms of depolarization ratio for aerosols, circular cylinder sea salt aerosols show the highest depolarization ratio at various relative humidities, followed by spheroid, with Chebyshev-shaped having the least. The effect of relative humidity on the depolarization ratio varies with the scattering angle. The higher the relative humidity, the more complex the variation in the depolarization ratio with scattering angle, with more pronounced oscillations in the curve, and the less non-spherical the shape, the more intense the oscillations in the depolarization ratio curve due to humidity. In conclusion, this study calculated the optical scattering and polarization properties of sea salt aerosol particles under different relative humidities and shapes, which is of significant importance for applications like 1.06 μm laser engineering and atmospheric radiation transmission in actual marine scenarios.
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