Molecular cloud formation in high-shear, magnetized colliding flows

The colliding flows (CF) model is a well-supported mechanism for generating molecular clouds. However, to-date most CF simulations have focused on the formation of clouds in the normal-shock layer between head-on colliding flows. We performed simulations of magnetized colliding flows that instead me...

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Veröffentlicht in:Monthly notices of the Royal Astronomical Society 2016-08, Vol.460 (2), p.2110-2128
Hauptverfasser: Fogerty, E., Frank, A., Heitsch, F., Carroll-Nellenback, J., Haig, C., Adams, M.
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Sprache:eng
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Zusammenfassung:The colliding flows (CF) model is a well-supported mechanism for generating molecular clouds. However, to-date most CF simulations have focused on the formation of clouds in the normal-shock layer between head-on colliding flows. We performed simulations of magnetized colliding flows that instead meet at an oblique-shock layer. Oblique shocks generate shear in the post-shock environment, and this shear creates inhospitable environments for star formation. As the degree of shear increases (i.e. the obliquity of the shock increases), we find that it takes longer for sink particles to form, they form in lower numbers, and they tend to be less massive. With regard to magnetic fields, we find that even a weak field stalls gravitational collapse within forming clouds. Additionally, an initially oblique collision interface tends to reorient over time in the presence of a magnetic field, so that it becomes normal to the oncoming flows. This was demonstrated by our most oblique shock interface, which became fully normal by the end of the simulation.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stw1141