Light propagation in scattering media based on Maxwell’s equations and on the radiative transfer equation

Felix Ott; Felix Ott; Dominik Reitzle; Dominik Reitzle; André Liemert; Alwin Kienle; Alwin Kienle

doi:10.1117/12.2670349

Diffuse Optical Spectroscopy and Imaging IX
Technical Digest Series (Optica Publishing Group, 2023),
paper 126281V
•https://doi.org/10.1117/12.2670349

Light propagation in scattering media based on Maxwell’s equations and on the radiative transfer equation

Felix Ott, Dominik Reitzle, André Liemert, and Alwin Kienle

European Conference on Biomedical Optics 2023

Munich Germany
25–29 June 2023
ISBN: 9781510664654

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Poster Session (PS12628)

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F. Ott, D. Reitzle, A. Liemert, and A. Kienle, "Light propagation in scattering media based on Maxwell’s equations and on the radiative transfer equation," in Diffuse Optical Spectroscopy and Imaging IX, Technical Digest Series (Optica Publishing Group, 2023), paper 126281V.

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Abstract

The light propagation in three-dimensional scattering media was studied based on solutions of Maxwell’s equations and the radiative transfer equation. The light distribution of laterally infinitely extended slabs was calculated versus depth for an incident plane wave. The energy density obtained by a numerical solution of Maxwell’s equations was compared to the fluence rate calculated by an analytical solution of the radiative transfer equation for different concentrations of spherical particles in the slab. In general, a good agreement between the energy density and the fluence rate was found. A small systematic difference was obtained at large concentrations of the scattering particles, which can be attributed to dependent scattering effects.

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