TY - JOUR
T1 - GALAXY OUTFLOWS WITHOUT SUPERNOVAE
AU - Sur, Sharanya
AU - Scannapieco, Evan
AU - Ostriker, Eve Charis
N1 - Funding Information:
We thank William Gray, Christopher Matzner, Prateek Sharma, and Robert Thacker for helpful discussions and the anonymous referee for comments. S.S. and E.S. were supported by the National Science Foundation grant AST11-03608 and NASA theory grants NNX09AD106 and NNX15AK82G. E.S. gratefully acknowledges the Simons Foundation for funding the workshop Galactic Winds: Beyond Phenomenology which helped to inspire this work. He also gratefully acknowledges Joanne Cohn, Eliot Quataert, and the UC Berkeley Theoretical Astronomy Center, and Uroš Seljak and the Lawrence Berkeley National Lab Cosmology group for hosting him during the period when much of this work was carried out. Part of this research was carried out during the visit of E.S. and E.C.O. at the KITP in UC Santa Barbara, which is supported by the National Science Foundation under grant PHY-1125915. The work of E.C.O. on this project was supported by the National Science Foundation under grant AST-1312006. The authors thank the Texas Advanced Computing Center (TACC) at The University of Texas at Austin (URL: http://www.tacc.utexas.edu) and the Extreme Science and Engineering Discovery Environment (XSEDE) for providing HPC resources via grant TG-AST140004 that have contributed to the results reported within this paper. The FLASH code is developed in part by the DOE-supported Alliances Center for Astrophysical Thermonuclear Flashes (ASC) at the University of Chicago.
Publisher Copyright:
© 2016. The American Astronomical Society. All rights reserved.
PY - 2016/2/10
Y1 - 2016/2/10
N2 - High surface density, rapidly star-forming galaxies are observed to have ≈50-100 km s-1 line of sight velocity dispersions, which are much higher than expected from supernova driving alone, but may arise from large-scale gravitational instabilities. Using three-dimensional simulations of local regions of the interstellar medium, we explore the impact of high velocity dispersions that arise from these disk instabilities. Parametrizing disks by their surface densities and epicyclic frequencies, we conduct a series of simulations that probe a broad range of conditions. Turbulence is driven purely horizontally and on large scales, neglecting any energy input from supernovae. We find that such motions lead to strong global outflows in the highly compact disks that were common at high redshifts, but weak or negligible mass loss in the more diffuse disks that are prevalent today. Substantial outflows are generated if the one-dimensional horizontal velocity dispersion exceeds ≈35 km s-1, as occurs in the dense disks that have star-formation rate (SFR) densities above ≈0.1 Mȯ yr-1 kpc-2. These outflows are triggered by a thermal runaway, arising from the inefficient cooling of hot material coupled with successive heating from turbulent driving. Thus, even in the absence of stellar feedback, a critical value of the SFR density for outflow generation can arise due to a turbulent heating instability. This suggests that in strongly self-gravitating disks, outflows may be enhanced by, but need not caused by, energy input from supernovae.
AB - High surface density, rapidly star-forming galaxies are observed to have ≈50-100 km s-1 line of sight velocity dispersions, which are much higher than expected from supernova driving alone, but may arise from large-scale gravitational instabilities. Using three-dimensional simulations of local regions of the interstellar medium, we explore the impact of high velocity dispersions that arise from these disk instabilities. Parametrizing disks by their surface densities and epicyclic frequencies, we conduct a series of simulations that probe a broad range of conditions. Turbulence is driven purely horizontally and on large scales, neglecting any energy input from supernovae. We find that such motions lead to strong global outflows in the highly compact disks that were common at high redshifts, but weak or negligible mass loss in the more diffuse disks that are prevalent today. Substantial outflows are generated if the one-dimensional horizontal velocity dispersion exceeds ≈35 km s-1, as occurs in the dense disks that have star-formation rate (SFR) densities above ≈0.1 Mȯ yr-1 kpc-2. These outflows are triggered by a thermal runaway, arising from the inefficient cooling of hot material coupled with successive heating from turbulent driving. Thus, even in the absence of stellar feedback, a critical value of the SFR density for outflow generation can arise due to a turbulent heating instability. This suggests that in strongly self-gravitating disks, outflows may be enhanced by, but need not caused by, energy input from supernovae.
KW - ISM: structure
KW - galaxies: evolution
KW - galaxies: starburst
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U2 - 10.3847/0004-637X/818/1/28
DO - 10.3847/0004-637X/818/1/28
M3 - Article
AN - SCOPUS:84959167642
SN - 0004-637X
VL - 818
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 1
M1 - 28
ER -