The First Positive Detection of Molecular Gas in a GRB Host Galaxy

J. X. Prochaska (1,2); Y. Sheffer (3); D.A. Perley (4); J. S. Bloom; (4); L. A. Lopez (2); M. Dessauges-Zavadsky (5); H.-W. Chen (6); A. V.; Filippenko (4); M. Ganeshalingam (4); W. Li (4); A. A. Miller (4); and D.; Starr (4,7) ((1) UC Santa Cruz; (2) UCO/Lick; (3) University of Toledo; (4); UC Berkeley; (5) Observatoire de Geneve; (6) U Chicago; (7) Las Cumbres; Observatory)

arXiv:0901.0556·astro-ph.HE·November 13, 2009

The First Positive Detection of Molecular Gas in a GRB Host Galaxy

J. X. Prochaska (1,2), Y. Sheffer (3), D.A. Perley (4), J. S. Bloom, (4), L. A. Lopez (2), M. Dessauges-Zavadsky (5), H.-W. Chen (6), A. V., Filippenko (4), M. Ganeshalingam (4), W. Li (4), A. A. Miller (4), and D., Starr (4,7) ((1) UC Santa Cruz, (2) UCO/Lick

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TL;DR

This paper reports the first detection of molecular gas (H2 and CO) in a gamma-ray burst host galaxy, revealing properties similar to Milky Way molecular clouds and providing insights into star formation in the early universe.

Contribution

It presents the first positive detection of molecular gas in a GRB host galaxy, analyzing its properties and implications for high-redshift star formation environments.

Findings

01

Detection of strong H2 and CO absorption in a GRB host galaxy.

02

Molecular gas properties similar to Milky Way translucent clouds.

03

High metallicity and dust-to-metals ratio indicating star formation environments.

Abstract

We report on strong H2 and CO absorption from gas within the host galaxy of gamma-ray burst (GRB) 080607. Analysis of our Keck/LRIS afterglow spectrum reveals a very large HI column density (NHI = 10^22.70 cm^-2) and strong metal-line absorption at z_GRB = 3.0363 with a roughly solar metallicity. We detect a series of A-X bandheads from CO and estimate N(CO) = 10^16.5 cm^-2 and T_ex^CO > 100K. We argue that the high excitation temperature results from UV pumping of the CO gas by the GRB afterglow. Similarly, we observe H2 absorption via the Lyman-Werner bands and estimate N(H2) = 10^21.2 cm^-2 with T_ex^H2 = 10--300K. The afterglow photometry suggests an extinction law with R_V=4 and A_V=3.2 mag and requires the presence of a modest 2175A bump. Additionally, modeling of the Swift/XRT X-ray spectrum confirms a large column density with N(H) = 10^22.58 cm^-2. Remarkably, this molecular…

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