http://arxiv.org/abs/1402.1788
We present the smoothed-particle hydrodynamics implementation SPHGal which incorporates several recent developments into the GADGET code. This includes a pressure-entropy formulation of SPH with a Wendland kernel, a higher order estimate of velocity gradients, a modified artificial viscosity switch with a strong limiter, and artificial conduction of thermal energy. We conduct a series of idealized hydrodynamic tests and show that while the pressure-entropy formulation is ideal for resolving fluid mixing at contact discontinuities, it performs conspicuously worse when strong shocks are involved due to the large entropy discontinuities. Including artificial conduction at shocks greatly improves the results. The Kelvin-Helmholtz instability can be resolved properly and dense clouds in the blob test dissolve qualitatively in agreement with other improved SPH implementations. We further perform simulations of an isolated Milky Way like disk galaxy and find a feedback-induced instability developing if too much artificial viscosity is introduced. Our modified artificial viscosity scheme not only prevents this instability but also shows efficient shock capturing capability in the Sedov explosion test. We also investigate the star formation rate and the galactic outflow of the MW disk as well as a gas-rich disk. The star formation rates vary slightly for different SPH schemes while the mass loading is quite sensitive to the SPH scheme. The galactic outflows are reduced due to more efficient fluid mixing. Finally, we compare the accretion behavior of of hot halo gas. The formation of cold blobs, an artifact of simple SPH implementations, can be eliminated efficiently with proper fluid mixing, either by conduction and/or by using a pressure-entropy formulation. Based on the performed tests we consider the SPHGal hydrodynamics sufficiently accurate for galaxy formation simulations.
C. Hu, T. Naab, S. Walch, et. al.
Tue, 11 Feb 14
32/55
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