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| Empirical Expression of Phase Function for Non-Spherical Particles |
| CHENG Chen1, XU Qing-shan1*, ZHU Lin1,2 |
1. Laboratory of Photoelectic Detection, Center of Fundamental Science, Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Hefei 230031, China
2. Science Island Branch of Graduate School, University of Science and Technology of China, Hefei 230031, China |
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Abstract In electromagnetic radiative transfer calculations, the accuracy and the computation timeare usually determined by the representation of scattering phase function. Accurate calculations are time consuming even for non-spherical particles. In order to get a better fit to exact calculations and simulate the backward-scattering peak of non-spherical particles, we developed a new empirical expression of non-spherical based on the fundamental theory of electromagnetic scattering and radiation transmission. This empirical expression of phase function is an algebraic expression with one single free parameter(asymmetry factor), and can be expanded into Legendre polynomials. We compared the Henyey-Greenstein* phase function and the new empirical expression with the T-matrix method for dustlike aerosol with different geometric shape, and found the new empirical expression provided a more realistic description for the scattering of non-spherical particles. Furthermore, the calculated value for ratio of scattering intensity at 90 degree to the scattered intensity in the backward direction is more reasonable when the ratio of the horizontal to rotational axes and the diameter-to-length ratio is larger than 0.5. We also investigated the effectiveness in approximating scattering from polydispersed particles by comparison between the new empirical expression, the Henyey-Greenstein* phase function and the T-matrix method for four of the log normal distribution polydispersions. The results show that the new empirical expression fits the T-matrix method much better than the Henyey-Greenstein* phase function. For the new empirical expression, the RMSE is small for 100% data except for the ellipsoidal oceanic aerosol at the wavelength of 633 nm. Similarly, the effectiveness of the new empirical expression is significant when we calculate the ratio of scattered intensity at 90 degree to the scattered intensity in the backward direction of non-spherical aerosol. In summary, the new empirical expression provides more accurate calculation for scattered intensity of non-spherical particlesin the backward direction, and is helpful in electromagnetic radiative transfer calculations, and the reformatting radiative transfer models in terms of the new empirical expression should require relatively less effort.
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Received: 2017-06-04
Accepted: 2017-10-25
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Corresponding Authors:
XU Qing-shan
E-mail: qshxu@aiofm.ac.cn
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[1] XU Li-sheng, CHEN Hong-bin, DING Ji-lie(许丽生, 陈洪滨, 丁继烈). Advanses in Earth Science(地球科学进展), 2014, 29(18): 903.
[2] HUANG Chao-jun, WU Zhen-sen, LIU Ya-feng(黄朝军,吴振森,刘亚峰). Infrared and Laser Engineering(红外与激光工程), 2012, 41(3): 580.
[3] Taflove A, Hagness S C. Computational Electrodynamics. Boston: Artech House, 2000. 2.
[4] Mishchenko M I. Optics and Image Science, 1991, 8: 871.
[5] SUN Xian-ming, WANG Hai-hua, LIU Wan-qiang(孙贤明, 王海华, 刘万强). Acta Optica Sinica(光学学报), 2010, 30(5): 1505.
[6] BAI Lu, TANG Shuang-qing, WU Zhen-sen(白 璐, 汤双庆, 吴振森). Acta Phys. Sin.(物理学报), 2010, 59(3): 1749.
[7] LUO Shuang, YIN Qiu(罗 双, 尹 球). Acta Optica Sinica(光学学报), 2017, 37(2): 0229002-1.
[8] Wang Z, Cui S C, Yang J, et al. J. Quant. Spectrosc. Radiat. Transfer, 2017, 189: 283.
[9] Van de Hulst H C. Light Scattering by Small Particles. New York: Wiley, 1957. 8.
[10] Liou K N. An Introduction to Atmospheric Radiation. 2rd ed. Beijing: China Meteorological Press, 2004. 181.
[11] Mishchenko M I,Travis L D. J. Quant. Spectrosc. Radiat. Transfer, 1998, 60(3): 309.
[12] HU Shuai, GAO Tai-chang, LIU Lei(胡 帅,高太长,刘 磊). Journal of the Meteorological Sciences(气象学报), 2014, 34(6): 612. |
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