Radiative transfer simulations in astrophysics  

• Interstellar dust: formation and destruction, shapes, size distribution, optical and calorimetric • properties. • The radiative transfer equation: derivation, source and sink terms, line and continuum • transport, scattering by dust, dust absorption and re-emission in local equilibrium conditions. • The photon package life cycle: Monte Carlo basics, primary emission, interactions with the • dust, escape and detection, panchromatic simulations and dust emission. • Spatial grids: grid traversal, regular Cartesian grids, hierarchical grids, Voronoi grids. • Sampling from spatial distributions: random number generators, inversion method, rejection • method, decorating geometries with spiral arms or clumps, importing hydrodynamics • simulation results. • Optimization techniques: forced scattering, continuous absorption, peel-off, composite Credits 6.0 Study time 180 h Teaching languages Keywords Position of the course Contents Course size (nominal values; actual values may depend on programme) (Approved) 1 Access to this course unit via a credit contract is determined after successful competences assessment This course unit cannot be taken via an exam contract end-of-term and continuous assessment examination during the second examination period is not possible Assignment Group work, lecture, independent work • biasing. • Parallelization: shared and distributed memory, redistribution of parallel data between • simulation phases, performance scaling. • Inverse radiative transfer: fitting analytical models to observations, searching large parameter • spaces. • Extensions to the basic radiative transfer equation: dust heating in nonequilibrium conditions, • polarization, kinematics, radiation hydrodynamics. • Other radiative transfer simulation techniques: ray-tracing, moment method, dealing with high • optical depth, benchmark efforts. Several of these subjects are illustrated with astrophysical science cases, and the accompanying practical project links directly into many of the theoretical subjects. Final competences: 1 Derive the radiative transfer equation and understand its components. 2 Describe the Monte Carlo photon package life cycle and related techniques for spatial discretization, sampling from three-dimensiomal distributions, computational optimization, and parallelization. 3 Explain the pros and cons of the various techniques used in radiative transfer simulations. 4 Describe some science cases to which to radiative transfer simulations are applied and 1 explain why they are relevant. 5 Apply a state-of-the-art radiative transfer code to basic science cases. 6 Adjust a scientific code written in C++ to specific research demands. 7 Interpret radiative transfer simulation results in a numerical and astrophysical context. 8 Orally convey the findings of a radiative transfer simulation project to experts.
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Radiative transfer simulations in astrophysics
English

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