%0 Generic %1 buntemeyer2015radiation %A Buntemeyer, Lars %A Banerjee, Robi %A Peters, Thomas %A Klassen, Mikhail %A Pudritz, Ralph E. %D 2015 %K flash hydrodynamics radiation %T Radiation Hydrodynamics using Characteristics on Adaptive Decomposed Domains for Massively Parallel Star Formation Simulations %U http://arxiv.org/abs/1501.04501 %X We present an algorithm for solving the radiative transfer problem on massively parallel computers using adaptive mesh refinement and domain decomposition. The solver is based on the method of characteristics which requires an adaptive raytracer that integrates the equation of radiative transfer. The radiation field is split into local and global components which are handled separately to overcome the non-locality problem. The solver is implemented in the framework of the magneto-hydrodynamics code FLASH and is coupled by an operator splitting step. The goal is the study of radiation in the context of star formation simulations with a focus on early disc formation and evolution. This requires a proper treatment of radiation physics that covers both the optically thin as well as the optically thick regimes and the transition region in particular. We successfully show the accuracy and feasibility of our method in a series of standard radiative transfer problems and two 3D collapse simulations resembling the early stages of protostar and disc formation.

@misc{buntemeyer2015radiation, abstract = {We present an algorithm for solving the radiative transfer problem on massively parallel computers using adaptive mesh refinement and domain decomposition. The solver is based on the method of characteristics which requires an adaptive raytracer that integrates the equation of radiative transfer. The radiation field is split into local and global components which are handled separately to overcome the non-locality problem. The solver is implemented in the framework of the magneto-hydrodynamics code FLASH and is coupled by an operator splitting step. The goal is the study of radiation in the context of star formation simulations with a focus on early disc formation and evolution. This requires a proper treatment of radiation physics that covers both the optically thin as well as the optically thick regimes and the transition region in particular. We successfully show the accuracy and feasibility of our method in a series of standard radiative transfer problems and two 3D collapse simulations resembling the early stages of protostar and disc formation.}, added-at = {2015-01-20T10:11:55.000+0100}, author = {Buntemeyer, Lars and Banerjee, Robi and Peters, Thomas and Klassen, Mikhail and Pudritz, Ralph E.}, biburl = {https://www.bibsonomy.org/bibtex/2e8b455de151db36dc29762c8546b874f/miki}, description = {[1501.04501] Radiation Hydrodynamics using Characteristics on Adaptive Decomposed Domains for Massively Parallel Star Formation Simulations}, interhash = {c347265f636324d8b96eb6162e893b28}, intrahash = {e8b455de151db36dc29762c8546b874f}, keywords = {flash hydrodynamics radiation}, note = {cite arxiv:1501.04501Comment: 33 pages, 15 figures, prepared for submission to New Astronomy. Comments welcome}, timestamp = {2015-01-20T10:11:55.000+0100}, title = {Radiation Hydrodynamics using Characteristics on Adaptive Decomposed Domains for Massively Parallel Star Formation Simulations}, url = {http://arxiv.org/abs/1501.04501}, year = 2015 }