Bibcode
Richards, A. M. S.; Knapen, J. H.; Yates, J. A.; Cohen, R. J.; Collett, J. L.; Wright, M. M.; Gray, M. D.; Field, D.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 364, Issue 2, pp. 353-366.
Advertised on:
12
2005
Citations
20
Refereed citations
17
Description
We present Multi-Element Radio-Linked Interferometer Network (MERLIN)
observations of OH maser and radio continuum emission within a few
hundred pc of the core of the ultraluminous infrared galaxy (ULIRG)
Markarian 231. This is the only known OH megamaser galaxy classed as a
Seyfert 1. Maser emission is identified with the 1665- and 1667-MHz
transitions over a velocity extent of 720 km s-1. Both lines
show a similar position-velocity structure including a gradient of 1.7
km s-1 pc-1 from NW to SE along the 420-pc major
axis. The (unresolved) inner few tens of pc possess a much steeper
velocity gradient. The maser distribution is modelled as a torus
rotating about an axis inclined at ~45° to the plane of the sky. We
estimate the enclosed mass density to be 320 +/-
90Msolarpc-3 in a flattened distribution. This
includes a central unresolved mass of <~8 ×
106Msolar. All the maser emission is projected
against a region with a radio continuum brightness temperature
>=105 K, giving a maser gain of <=2.2. The 1667:1665
MHz line ratio is close to 1.8 (the value predicted for thermal
emission) consistent with radiatively pumped, unsaturated masers. This
behaviour and the kinematics of the torus suggest that the size of
individual masing regions is in the range 0.25-4 pc with a covering
factor close to unity. There are no very bright compact masers, in
contrast to galaxies such as the Seyfert 2 Markarian 273, where the
masing torus is viewed nearer edge-on. The comparatively modest maser
amplification seen from Markarian 231 is consistent with its
classification in the unification scheme for Seyfert galaxies. Most of
the radio continuum emission on 50-500 pc scales is probably of
starburst origin but the compact peak is 0.4 per cent polarized by a
magnetic field running north-south, similar to the jet direction on
these scales. There is no close correlation between maser and continuum
intensity, suggesting that much of the radio continuum must originate in
the foreground and indeed the relative continuum brightness is slightly
greater in the direction of the approaching jet. Comparisons with other
data show that the jet changes direction close the nucleus and suggest
that the sub-kpc disc hosting the masers and starburst activity is
severely warped.