The origin of molecular hydrogen emission in cooling-flow filaments

The origin of molecular hydrogen emission in cooling-flow filaments

The optical filaments found in many cooling flows in galaxy clusters consist of low-density (∼103 cm−3) cool (∼103 K) gas surrounded by significant amounts of cosmic-ray and magnetic field energy. Their spectra show anomalously strong low-ionization and molecular emission lines when compared with Ga...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society. Letters Vol. 386; no. 1; pp. L72 - L76
Main Authors: Ferland, G. J., Fabian, A. C., Hatch, N. A., Johnstone, R. M., Porter, R. L., Van Hoof, P. A. M., Williams, R. J. R.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Science Ltd 01-05-2008
Blackwell Publishing Ltd
Subjects:
galaxies: clusters: general
galaxies: clusters: individual: NGC 1275
galaxies: clusters: individual: NGC 4696
infrared: galaxies
intergalactic medium
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Summary:The optical filaments found in many cooling flows in galaxy clusters consist of low-density (∼103 cm−3) cool (∼103 K) gas surrounded by significant amounts of cosmic-ray and magnetic field energy. Their spectra show anomalously strong low-ionization and molecular emission lines when compared with Galactic molecular clouds exposed to ionizing radiation such as the Orion complex. Previous studies have shown that the spectra cannot be produced by O-star photoionization. Here, we calculate the physical conditions in dusty gas that is well shielded from external sources of ionizing photons and is energized either by cosmic rays or dissipative magnetohydrodynamics waves. Strong molecular hydrogen lines, with relative intensities similar to those observed, are produced. Selection effects introduced by the microphysics produce a correlation between the H2 line upper level energy and the population temperature. These selection effects allow a purely collisional gas to produce H2 emission that masquerades as starlight-pumped H2 but with intensities that are far stronger. This physics may find application to any environment where a broad range of gas densities or heating rates occur.
Bibliography:ark:/67375/HXZ-PHBL1LD7-Q
istex:4C7CD76A5988127237A96939E12AD173239EA7D6
Contains material © British Crown copyright 2008/MoD.
Contains material ©British Crown copyright 2008/MoD.
ISSN:1745-3925
1745-3933
DOI:10.1111/j.1745-3933.2008.00463.x