Far-field Lorenz–Mie scattering in an absorbing host medium: Theoretical formalism and FORTRAN program

•We study electromagnetic scattering by spherical particles immersed in an unbounded absorbing medium.•A first-principles approach allows for the calculation of relevant far-field optical observables.•This approach is implemented in the form of a public-domain FORTRAN program. In this paper we make...

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Veröffentlicht in:Journal of quantitative spectroscopy & radiative transfer Jg. 205; S. 241 - 252
Hauptverfasser: Mishchenko, Michael I., Yang, Ping
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Goddard Space Flight Center Elsevier Ltd 01.01.2018
Elsevier
Schlagworte:
Absorbing host medium
Computer Programming And Software
Far-field electromagnetic scattering
Lorenz–Mie theory
Macroscopic Maxwell equations
Physics (General)
Radiative transfer theory
Macroscopic Maxwell equations
Radiative transfer theory
Lorenz–Mie theory
Far-field electromagnetic scattering
Absorbing host medium
Far-Field Electromagnetic Scattering; Absorbing Host Medium; Lorenz–mie Theory
ISSN:0022-4073, 1879-1352
Online-Zugang:Volltext
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Abstract •We study electromagnetic scattering by spherical particles immersed in an unbounded absorbing medium.•A first-principles approach allows for the calculation of relevant far-field optical observables.•This approach is implemented in the form of a public-domain FORTRAN program. In this paper we make practical use of the recently developed first-principles approach to electromagnetic scattering by particles immersed in an unbounded absorbing host medium. Specifically, we introduce an actual computational tool for the calculation of pertinent far-field optical observables in the context of the classical Lorenz–Mie theory. The paper summarizes the relevant theoretical formalism, explains various aspects of the corresponding numerical algorithm, specifies the input and output parameters of a FORTRAN program available at https://www.giss.nasa.gov/staff/mmishchenko/Lorenz-Mie.html, and tabulates benchmark results useful for testing purposes. This public-domain FORTRAN program enables one to solve the following two important problems: (i) simulate theoretically the reading of a remote well-collimated radiometer measuring electromagnetic scattering by an individual spherical particle or a small random group of spherical particles; and (ii) compute the single-scattering parameters that enter the vector radiative transfer equation derived directly from the Maxwell equations.
AbstractList In this paper we make practical use of the recently developed first-principles approach to electromagnetic scattering by particles immersed in an unbounded absorbing host medium. Specifically, we introduce an actual computational tool for the calculation of pertinent far-field optical observables in the context of the classical Lorenzâ€"Mie theory. The paper summarizes the relevant theoretical formalism, explains various aspects of the corresponding numerical algorithm, specifies the input and output parameters of a FORTRAN program available at https://www.giss.nasa.gov/staff/mmishchenko/Lorenz-Mie.html, and tabulates benchmark results useful for testing purposes. This public-domain FORTRAN program enables one to solve the following two important problems: (i) simulate theoretically the reading of a remote well-collimated radiometer measuring electromagnetic scattering by an individual spherical particle or a small random group of spherical particles; and (ii) compute the single-scattering parameters that enter the vector radiative transfer equation derived directly from the Maxwell equations.
•We study electromagnetic scattering by spherical particles immersed in an unbounded absorbing medium.•A first-principles approach allows for the calculation of relevant far-field optical observables.•This approach is implemented in the form of a public-domain FORTRAN program. In this paper we make practical use of the recently developed first-principles approach to electromagnetic scattering by particles immersed in an unbounded absorbing host medium. Specifically, we introduce an actual computational tool for the calculation of pertinent far-field optical observables in the context of the classical Lorenz–Mie theory. The paper summarizes the relevant theoretical formalism, explains various aspects of the corresponding numerical algorithm, specifies the input and output parameters of a FORTRAN program available at https://www.giss.nasa.gov/staff/mmishchenko/Lorenz-Mie.html, and tabulates benchmark results useful for testing purposes. This public-domain FORTRAN program enables one to solve the following two important problems: (i) simulate theoretically the reading of a remote well-collimated radiometer measuring electromagnetic scattering by an individual spherical particle or a small random group of spherical particles; and (ii) compute the single-scattering parameters that enter the vector radiative transfer equation derived directly from the Maxwell equations.
Audience PUBLIC
Author Yang, Ping
Mishchenko, Michael I.
Author_xml – sequence: 1
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– sequence: 2
  givenname: Ping
  surname: Yang
  fullname: Yang, Ping
  organization: Department of Atmospheric Sciences, Texas A&M University, College Station, TX 77843, USA
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Keywords Macroscopic Maxwell equations
Radiative transfer theory
Lorenz–Mie theory
Far-field electromagnetic scattering
Absorbing host medium
Far-Field Electromagnetic Scattering; Absorbing Host Medium; Lorenz–mie Theory
Language English
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GSFC-E-DAA-TN49290
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Goddard Space Flight Center
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2018-01-01
2018-01-00
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PublicationPlace Goddard Space Flight Center
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PublicationTitle Journal of quantitative spectroscopy & radiative transfer
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Elsevier
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Snippet •We study electromagnetic scattering by spherical particles immersed in an unbounded absorbing medium.•A first-principles approach allows for the calculation...
In this paper we make practical use of the recently developed first-principles approach to electromagnetic scattering by particles immersed in an unbounded...
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SubjectTerms Absorbing host medium
Computer Programming And Software
Far-field electromagnetic scattering
Lorenz–Mie theory
Macroscopic Maxwell equations
Physics (General)
Radiative transfer theory
Title Far-field Lorenz–Mie scattering in an absorbing host medium: Theoretical formalism and FORTRAN program
URI https://dx.doi.org/10.1016/j.jqsrt.2017.10.014
https://ntrs.nasa.gov/citations/20180000963
Volume 205
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