Book contents
- Frontmatter
- Contents
- Preface
- Conference participants
- Conference photograph / poster
- 1 Physics of H2 and HD
- Astrophysical Importance of H2
- Radiative and Electronic Excitation of Lyman and Werner Transitions in H2
- The Cooling of Astrophysical Media by H2 and HD
- Highly Excited Singlet Ungerade States of H2 and their Theoretical Description
- Laboratory Studies of Long-range Excited States of H2
- A Model of Interstellar Dark Matter
- Mass of H2 Dark Matter in the Galactic Halo
- 2 Formation - Destruction
- 3 Observations and Models
- 4 Extragalactic and Cosmology
- 5 Outlook
- Author index
The Cooling of Astrophysical Media by H2 and HD
from 1 - Physics of H2 and HD
Published online by Cambridge University Press: 04 August 2010
- Frontmatter
- Contents
- Preface
- Conference participants
- Conference photograph / poster
- 1 Physics of H2 and HD
- Astrophysical Importance of H2
- Radiative and Electronic Excitation of Lyman and Werner Transitions in H2
- The Cooling of Astrophysical Media by H2 and HD
- Highly Excited Singlet Ungerade States of H2 and their Theoretical Description
- Laboratory Studies of Long-range Excited States of H2
- A Model of Interstellar Dark Matter
- Mass of H2 Dark Matter in the Galactic Halo
- 2 Formation - Destruction
- 3 Observations and Models
- 4 Extragalactic and Cosmology
- 5 Outlook
- Author index
Summary
We summarize the results of recent quantum mechanical calculations of cross sections and rate coefficients for the rovibrational excitation of H2 and HD by the principal perturbers, H, He, and H2. These results have been used to evaluate the rate of cooling of astrophysical media by H2 and HD molecules; these calculations are also described. The cooling of the primordial gas by rotational transitions of H2 is considered as a special case.
All the numerical results and related software are available from http://ccp7.dur.ac.uk/.
Introduction
Molecular hydrogen is recognized as a major contributor to the cooling of astrophysical media. Its role is all the more significant under conditions, such as those which prevailed in the primordial gas, where few other coolants were present; but H2 is also an important, sometimes the dominant coolant of low density interstellar gas, for kinetic temperatures T > 100 K. Interstellar gas can be heated to such temperatures by shock waves, by the dissipation of turbulence, or by absorbing energy from the local ultraviolet radiation field, as in photon-dominated regions.
Although the elemental abundance of deuterium is approximately 5 orders of magnitude less than that of hydrogen, it turns out that cooling by HD must often be taken into account, essentially for two reasons. First, chemical fractionation can, in media which are only partially molecular, enhance the abundance of HD, relative to that of H2.
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- Molecular Hydrogen in Space , pp. 23 - 30Publisher: Cambridge University PressPrint publication year: 2000
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