A general and computationally fast formulation for radiative transfer with scattering
Abstract
A general formulation of monocromatic radiative transfer with scattering has been developed for plane-parallel geometry. The inhomogeneous and nonisothermal medium absorbs, emits, and anisotropically scatters radiation. Surfaces can emit and scatter radiation in any specified manner. The solution procedure uses the fact that phase incoherent scattering is linear in radiative sources. Certain basic scattering functions are then defined and calculated by an adding computer code using matrix algebra. These scattering functions are weighted by the temperature field and summed (superimposed) to obtain the solution for any specific problem. Numerical results for exiting intensities and one-sided heat fluxes from general media bound by one arbitrary surface are presented. These parametric studies demonstrate the effects of scattering particles and surfaces on radiative transfer from inhomogeneous and nonisothermal media. Application of the formulation to radiative equilibrium is also discussed. The conclusion is that all problems in plane-parallel radiative transfer with scattering can be solved by a common and computationally fast algorithm based on this formulation.
- Publication:
-
American Institute of Aeronautics and Astronautics
- Pub Date:
- June 1979
- Bibcode:
- 1979thph.confR....C
- Keywords:
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- Algorithms;
- Monochromatic Radiation;
- Radiative Heat Transfer;
- Emissivity;
- Heat Flux;
- Reflectance;
- Scattering;
- Thermodynamic Equilibrium;
- Fluid Mechanics and Heat Transfer