We present radiation-magnetohydrodynamic simulations aimed at studying evolutionary properties of HII regions in turbulent, magnetized, and collapsing molecular clouds formed by converging flows in the warm neutral medium. We focus on the structure, dynamics, and expansion laws of these regions. Once a massive star forms in our highly structured clouds, its ionizing radiation eventually stops the accretion (through filaments) towards the massive starforming regions. The new overpressured HII regions push away the dense gas, thus disrupting the more massive collapse centres. Also, because of the complex density structure in the cloud, the HII regions expand in a hybrid manner: they virtually do not expand towards the densest regions (cores), while they expand according to the classical analytical result towards the rest of the cloud, and in an accelerated way, as a blister region, towards the diffuse medium. Thus, the ionized regions grow anisotropically, and the ionizing stars generally appear off-centre of the regions. Finally, we find that the hypotheses assumed in standard HII-region expansionmodels (fully embedded region, blister-type, or expansion in a density gradient) apply simultaneously in different parts of our simulated HII regions, producing a net expansion law (R α tα, with α in the range of 0.93.1.47 and a mean value of 1.2 ± 0.17) that differs from any of those of the standard models.

Structure and expansion law of HII regions in structured molecular clouds

Shore S. N.;
2019-01-01

Abstract

We present radiation-magnetohydrodynamic simulations aimed at studying evolutionary properties of HII regions in turbulent, magnetized, and collapsing molecular clouds formed by converging flows in the warm neutral medium. We focus on the structure, dynamics, and expansion laws of these regions. Once a massive star forms in our highly structured clouds, its ionizing radiation eventually stops the accretion (through filaments) towards the massive starforming regions. The new overpressured HII regions push away the dense gas, thus disrupting the more massive collapse centres. Also, because of the complex density structure in the cloud, the HII regions expand in a hybrid manner: they virtually do not expand towards the densest regions (cores), while they expand according to the classical analytical result towards the rest of the cloud, and in an accelerated way, as a blister region, towards the diffuse medium. Thus, the ionized regions grow anisotropically, and the ionizing stars generally appear off-centre of the regions. Finally, we find that the hypotheses assumed in standard HII-region expansionmodels (fully embedded region, blister-type, or expansion in a density gradient) apply simultaneously in different parts of our simulated HII regions, producing a net expansion law (R α tα, with α in the range of 0.93.1.47 and a mean value of 1.2 ± 0.17) that differs from any of those of the standard models.
2019
Zamora-Aviles, M.; Vazquez-Semadeni, E.; Gonzalez, R. F.; Franco, J.; Shore, S. N.; Hartmann, L. W.; Ballesteros-Paredes, J.; Banerjee, R.; Kortgen, B...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11568/1023332
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