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Global Evolution of a Self-Gravitating Multi-Phase ISM in the Central Kpc Region of Galaxies

from Part 4 - Physical Processes in Bulge Formation

Published online by Cambridge University Press:  10 November 2010

K. Wada
Affiliation:
Johns Hopkins University, 3400 N. Charles Street, Baltimore MD 21218, USA; National Astronomical Observatory, Mitaka, 181, Japan
C.A. Norman
Affiliation:
Johns Hopkins University, 3400 N. Charles Street, Baltimore MD 21218, USA
C. Marcella Carollo
Affiliation:
Columbia University, New York
Henry C. Ferguson
Affiliation:
Space Telescope Science Institute, Baltimore
Rosemary F. G. Wyse
Affiliation:
The Johns Hopkins University
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Summary

Using high resolution, two-dimensional hydrodynamical simulations, we investigate the evolution of a self-gravitating multi-phase interstellar medium in the central kiloparsec region of a galactic disk. We find that a gravitationally and thermally unstable disk evolves, in a self-stabilizing manner, into a globally quasi-stable disk that consists of cold (T < 100 K), dense clumps and filaments surrounded by hot (T > 104 K), diffuse medium. In the quasi-stable phase where cold and dense clouds are formed, the effective stability parameter, Q, has a value in the range 2-5. The dynamic range of our multi-phase calculations is 106 – 107 in both density and temperature. Phase diagrams for this turbulent medium are analyzed and discussed. We also succeeded in modeling star formation in the multi-phase ISM with 2 pc resolution. Massive stars formed in the dense, cold clouds are tracked for their life time, and finally explode as SNe. The filamentlike structure of the cold gas is stable for the SNe, although bubbles of the hot gas (T > 106 K) are formed. We observed recurrent burst-like SNe production.

Introduction

We model the multi-phase and inhomogeneous interstellar medium (ISM) in the inner region of a galactic disk including fundamental physical processes crucial for understanding star formation, global and local dynamics of the ISM in galaxies, and aspects of galaxy formation such as feedback. Most numerical simulations of the ISM and of star formation in galaxies have assumed simpler ISM models, e.g. an isothermal or nearly-isothermal equation of state, and either a smooth medium or discrete clouds.

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Publisher: Cambridge University Press
Print publication year: 2000

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