Light scattering by absorbing hexagonal ice crystals in cirrus clouds

Jianyun Zhang; Lisheng Xu

doi:10.1364/AO.34.005867

Applied Optics
Vol. 34,
Issue 25,
pp. 5867-5874
(1995)
•https://doi.org/10.1364/AO.34.005867

Light scattering by absorbing hexagonal ice crystals in cirrus clouds

Jianyun Zhang and Lisheng Xu

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Jianyun Zhang and Lisheng Xu, "Light scattering by absorbing hexagonal ice crystals in cirrus clouds," Appl. Opt. 34, 5867-5874 (1995)

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Abstract

An improved ray-optics theory for single scattering and polarization of hexagonal columns and plates randomly oriented in space has been developed by considering absorption and by using the Chebyshev solution for diffraction integrals. The vector-tracing method and statistics technique of random sampling are employed. The equivalent forms of Snell’s law and Fresnel formulas for absorbing ice crystals are derived, and two equivalent optical constants, m′ and m″, are obtained. Comparison is made of the computed results of our model and the Takano and Liou model for asymmetry factors, single-scattering albedos, and scattering phase matrix elements. Some characteristics of our model are discussed, and these analyses demonstrate that our ray-optics model is practical and much improved.

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Particle Size L/2a (μm/μm)	λa (μm)	1 − ${\tilde{ω}}_{0}$		g

		TL Model	ZX Model	TL Model	ZX Model
20/20	0.55	0	0	0.7704	0.7713
	2.20	0.0409	0.0452	0.8185	0.8157
50/40	0.55	0	0	0.7780	0.7818
	2.20	0.0818	0.0900	0.8416	0.8300
120/60	0.55	0	0	0.8155	0.8132
	2.20	0.1246	0.1402	0.8829	0.8640
300/100	0.55	0	0	0.8429	0.8379
	2.20	0.1871	0.2103	0.9165	0.8827
750/160	0.55	0	0	0.8592	0.8565
	2.20	0.2503	0.2277	0.9380	0.8987

Particle Size L/2a (μm/μm)	N	m _r = 1.263	m _i = 7.997 × 10⁻⁴	m _r = 1.263	m _i = 0

		${\tilde{ω}}_{0}$	g	${\tilde{ω}}_{0}$	g
300/100	3 × 10⁵	0.7884	0.8828	1.0000	0.7985
	3.5 × 10⁵	0.7886	0.8828
	4 × 10⁵	0.7888	0.8829
750/160	3 × 10⁵	0.7230	0.8988	1.0000	0.8300
	3.5 × 10⁵	0.7231	0.8989
	4 × 10⁵	0.7263	0.8990

Particle Size L/2a (μm/μm)	λa (μm)	1 − ${\tilde{ω}}_{0}$		g

		TL Model	ZX Model	TL Model	ZX Model
20/20	0.55	0	0	0.7704	0.7713
	2.20	0.0409	0.0452	0.8185	0.8157
50/40	0.55	0	0	0.7780	0.7818
	2.20	0.0818	0.0900	0.8416	0.8300
120/60	0.55	0	0	0.8155	0.8132
	2.20	0.1246	0.1402	0.8829	0.8640
300/100	0.55	0	0	0.8429	0.8379
	2.20	0.1871	0.2103	0.9165	0.8827
750/160	0.55	0	0	0.8592	0.8565
	2.20	0.2503	0.2277	0.9380	0.8987

Particle Size L/2a (μm/μm)	N	m _r = 1.263	m _i = 7.997 × 10⁻⁴	m _r = 1.263	m _i = 0

		${\tilde{ω}}_{0}$	g	${\tilde{ω}}_{0}$	g
300/100	3 × 10⁵	0.7884	0.8828	1.0000	0.7985
	3.5 × 10⁵	0.7886	0.8828
	4 × 10⁵	0.7888	0.8829
750/160	3 × 10⁵	0.7230	0.8988	1.0000	0.8300
	3.5 × 10⁵	0.7231	0.8989
	4 × 10⁵	0.7263	0.8990

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Applied Optics