On the Convergence of Numerical Computations for Both Exact and Approximate Solutions for Electromagnetic Scattering by Nonspherical Dielectric Particles.

IF 6.1 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Ping Yang, Jiachen Ding, Richard Lee Panetta, Kuo-Nan Liou, George W Kattawar, Michael Mishchenko
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Abstract

We summarize the size parameter range of the applicability of four light-scattering computational methods for nonspherical dielectric particles. These methods include two exact methods - the extended boundary condition method (EBCM) and the invariant imbedding T-matrix method (II-TM) and two approximate approaches - the physical-geometric optics method (PGOM) and the improved geometric optics method (IGOM). For spheroids, the single-scattering properties computed by EBCM and II-TM agree for size parameters up to 150, and the comparison gives us confidence in using IITM as a benchmark for size parameters up to 150 for other geometries (e.g., hexagonal columns) because the applicability of II-TM with respect to particle shape is generic, as demonstrated in our previous studies involving a complex aggregate. This study demonstrates the convergence of the exact II-TM and approximate PGOM solutions for the complete set of single-scattering properties of a nonspherical shape other than spheroids and circular cylinders with particle sizes of ~ 48λ(size parameter ~150), specifically a hexagonal column with a length size parameter of kL = 300 where k = 2π/λ and L is the column length. IGOM is also quite accurate except near the exact 180°backscattering direction. This study demonstrates that a synergetic combination of the numerically-exact II-TM and the approximate PGOM can seamlessly cover the entire size parameter range of practical interest. To demonstrate the applicability of the approach, we compute the optical properties of dust particles and demonstrate a downstream application to the retrieval of dust aerosol optical thickness and effective particle size from satellite polarimetric observations.

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非球形介电粒子电磁散射精确解和近似解数值计算的收敛性。
总结了四种光散射计算方法对非球形介电粒子适用性的尺寸参数范围。这些方法包括两种精确方法——扩展边界条件法(EBCM)和不变嵌入t矩阵法(II-TM),以及两种近似方法——物理几何光学法(PGOM)和改进几何光学法(IGOM)。对于椭球体,EBCM和II-TM计算的单散射特性在尺寸参数高达150的情况下是一致的,比较使我们有信心使用IITM作为其他几何形状(例如六角形柱)尺寸参数高达150的基准,因为II-TM在颗粒形状方面的适用性是通用的,正如我们之前涉及复杂聚集体的研究所证明的那样。对于粒径为~ 48λ(粒径参数为~150)的非球形球体和圆柱体,特别是长度参数为kL = 300的六角形柱,其中k = 2π/λ, L为柱长,本文证明了精确II-TM解和近似PGOM解的收敛性。除了接近精确的180°后向散射方向外,IGOM也非常精确。该研究表明,数值精确的II-TM和近似PGOM的协同组合可以无缝覆盖实际关注的整个尺寸参数范围。为了证明该方法的适用性,我们计算了尘埃颗粒的光学特性,并演示了从卫星偏振观测中检索尘埃气溶胶光学厚度和有效粒径的下游应用。
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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CiteScore
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