Fresnel reflection boundary for radiative transport lattice Boltzmann methods in highly scattering volume
With its roots in kinetic theory, the lattice Boltzmann method (LBM) cannot only be used to solve complex fluid flows but also radiative transport in volume. The present work derives a novel Fresnel boundary scheme for radiative transport LBM, based on Fresnel's equation, which depicts the part...
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Zusammenfassung: | With its roots in kinetic theory, the lattice Boltzmann method (LBM) cannot
only be used to solve complex fluid flows but also radiative transport in
volume. The present work derives a novel Fresnel boundary scheme for radiative
transport LBM, based on Fresnel's equation, which depicts the partly reflected
radiation on surfaces. Driven from a boundary modeling and discussion on the
microscopic level, incorporating Fresnel's equation, it is developed a boundary
model for the mesoscopic radiative transport LBM. At an intermediate step, the
Fresnel's equation is related to well known partial differential (Robin)
equations, based on a bottom-up approach where the P1-Approximation is
deployed. To connect the novel boundary scheme to the so derived target
equation, a Chapman-Enskog expansion is examined in addition. Both techniques
together, point out how to interpret microscopic modeling by the means of
macroscopic expressions and as a consequence how, to chose simulation
parameters according to the specific boundary. The numerical tests suggest that
the proposed boundary is first order convergent. The paper closes with a
showcase, where the novel boundary method for radiative transport LBM is
applied to a setup with multiple LED spots. |
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DOI: | 10.48550/arxiv.2107.09411 |