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Radiative Transfer For Variable 3D Atmospheres

Numerical Analysis 2023-01-25 v1 Numerical Analysis Analysis of PDEs

Abstract

To study the temperature in a gas subjected to electromagnetic radiations, one may use the Radiative Transfer equations coupled with the Navier-Stokes equations. The problem has 7 dimensions; however with minimal simplifications it is equivalent to a small number of integro-differential equations in 3 dimensions. We present the method and a numerical implementation using an H-matrix compression scheme. The result is a very fast: 50K physical points, all directions of radiation and 680 frequencies require less than 5 minutes on an Apple M1 Laptop. The method is capable of handling variable absorptioN and scattering functionS of spatial positions and frequencies. The implementation is done using htool, a matrix compression library interfaced with the PDE solver freefem++. Applications to the temperature in the French Chamonix valley is presented at different hours of the day with and without snow / clouds and with a variable absorption taken from the Gemini measurements. The result is precise enough to assert temperature differences due to increased absorption in the vibrational frequency subrange of greenhouse gasses.

Cite

@article{arxiv.2208.06410,
  title  = {Radiative Transfer For Variable 3D Atmospheres},
  author = {Francois Golse and Frederic Hecht and Olivier Pironneau and Pierre-Henri Tournier and Didier Smets},
  journal= {arXiv preprint arXiv:2208.06410},
  year   = {2023}
}
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