Scattering matrices for large ice crystal particles

Borovoi, Anatoli G.; Grishin, I. A.

doi:10.1364/josaa.20.002071

Cited by 77 publications

(28 citation statements)

References 17 publications

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“…Then del Guasta [6] developed a code named the facet tracing and applied it to calculate the backscatter by hexagonal ice crystals. Also the analogous codes were developed and used by Romashov [7], by Borovoi and Grishin [8] and by Borovoi et al [9]. Recently, the same beam-splitting code was considered by Bi et al [10] where the case of absorbing crystals was included as well.…”

Section: Introductionmentioning

confidence: 99%

Beam-splitting code for light scattering by ice crystal particles within geometric-optics approximation

Konoshonkin

Kustova

Borovoi

2015

Journal of Quantitative Spectroscopy and Radiative Transfer

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Section: Introductionmentioning

confidence: 99%

Beam-splitting code for light scattering by ice crystal particles within geometric-optics approximation

Konoshonkin

Kustova

Borovoi

2015

Journal of Quantitative Spectroscopy and Radiative Transfer

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“…These clouds also pose a challenge to atmospheric radiative transfer and remote sensing studies. As the optical properties of ice crystals are fundamental to quantifying the radiative properties of ice clouds, the atmospheric research community has made a significant effort to investigate the single-scattering properties of ice particles (Takano and Liou 1989a;Macke et al 1996;Yang and Liou 1996;Borovoi and Grishin 2003;Baran et al 2001;Baran 2004;Um and McFarquhar 2007;Zhang et al 2009). For practical applications to atmospheric radiative transfer and remote sensing involving ice clouds, the singlescattering properties (i.e., the phase matrix, singlescattering albedo, asymmetry factor, and extinction cross section) of individual ice crystals need to be integrated over particle size and shape distributions to derive the bulk optical properties (Ebert and Curry 1992;Fu 1996;Key et al 2002;McFarquhar et al 2002;Baum et al 2000Baum et al , 2005.…”

Section: Introductionmentioning

confidence: 99%

On the Use of Scattering Kernels to Calculate Ice Cloud Bulk Optical Properties

Liu

Ding

et al. 2012

Journal of Atmospheric and Oceanic Technology

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Nonspherical ice crystal optical properties are of fundamental importance to atmospheric radiative transfer through an ice cloud and the remote sensing of its properties. In practice, the optical properties of individual ice crystals need to be integrated over particle size distributions to derive the bulk optical properties of ice clouds. Given a particle size distribution represented in terms of size bins, the conventional approach uses the microphysical and optical properties of ice crystals at the bin centers as approximations to the bin-averaged values. However, errors are incurred when the size bins are large. To reduce the potential errors, a kernel technique is utilized to calculate the bulk optical properties of ice clouds by computing the bin-averaged values instead of using the bin-center values. Comparisons between the solutions based on the conventional method and the kernel technique for different numbers of size bins from in situ measurements demonstrate that the results computed from the kernel technique are more accurate. The present study illustrates that, for a given size distribution, 40 or more size bins should be used to calculate the bulk optical properties of ice clouds by the conventional method. Although the accuracy of bulk-scattering properties can be improved by using fine bin resolutions in the single-scattering property computation, the advantage of using a precomputed database of scattering kernels allows efficient computation of ice cloud bulk optical properties without losing the accuracy.

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“…In particular, we use the physical-optics approximation [6] to calculate light backscattering by hexagonal ice crystals of cirrus clouds. This reciprocity allows us to estimate a reliability of such calculations.…”

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“…For such a large particle with the realvalued, for simplicity, refractive index, the scattered field inside the particle is easy found in geometric optics approximation by drawing ray trajectories. As a result, the scattered light leaves the particle after a number of internal reflections as a set of plane-parallel beams or ray bundles [6]. Every outgoing beam is determined on the particle surface by a number of parameters.…”

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Backscattering reciprocity for large particles

2013

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The backscattering reciprocity theorem is considered for large particles as compared with the incident wavelength particles of arbitrary shape. It is shown that, in the specific case of faceted particles, this theorem is provided by the appearance of pairs of conjugate backscattered beams. A parameter characterizing a deviation of any approximation from the reciprocity theorem is proposed, and it is used for estimation of reliability for the physical-optics approximation.

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Scattering matrices for large ice crystal particles

Cited by 77 publications

References 17 publications

Beam-splitting code for light scattering by ice crystal particles within geometric-optics approximation

Beam-splitting code for light scattering by ice crystal particles within geometric-optics approximation

On the Use of Scattering Kernels to Calculate Ice Cloud Bulk Optical Properties

Backscattering reciprocity for large particles

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