Abstract
Long gamma-ray bursts (GRBs), among the most energetic events in the
Universe, are explosions of massive and short-lived stars, so they pinpoint
locations of recent star formation. However, several GRB host galaxies have
recently been found to be deficient in molecular gas (H2), believed to be the
fuel of star formation. Moreover, optical spectroscopy of GRB afterglows
implies that the molecular phase constitutes only a small fraction of the gas
along the GRB line-of-sight. Here we report the first ever 21 cm line
observations of GRB host galaxies, using the Australia Telescope Compact Array,
implying high levels of atomic hydrogen (HI), which suggests that the
connection between atomic gas and star formation is stronger than previously
thought, with star formation being potentially directly fuelled by atomic gas
(or with very efficient HI-to-H2 conversion and rapid exhaustion of molecular
gas), as has been theoretically shown to be possible. This can happen in low
metallicity gas near the onset of star formation, because cooling of gas
(necessary for star formation) is faster than the HI-to-H2 conversion. Indeed,
large atomic gas reservoirs, together with low molecular gas masses, stellar
and dust masses are consistent with GRB hosts being preferentially galaxies
which have very recently started a star formation episode after accreting
metal-poor gas from the intergalactic medium. This provides a natural route for
forming GRBs in low-metallicity environments. The gas inflow scenario is also
consistent with the existence of the companion HI object with no optical
counterpart ~19 kpc from the GRB 060505 host, and with the fact that the HI
centroids of the GRB 980425 and 060505 hosts do not coincide with optical
centres of these galaxies, but are located close to the GRB positions.
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