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Astron. Astrophys. 343, L79-L82 (1999)
Letter to the Editor
HI and OH absorption at z = 0.89
Jayaram N. Chengalur 1,
A.G. deBruyn 2,3 and
D. Narasimha 4
1 NCRA-TIFR, PO Bag 3, Ganeshkhind, Pune 411007, India
2 Netherlands Foundation for Research in Astronomy, P.O. Box 2, 7990 AA, Dwingeloo, The Netherlands
3 Kapteyn Astronomical Institute, P.O. Box 800, 9700 AA, Groningen, The Netherlands
4 Tata Institute of Fundamental Research, Homi Bhaba Road, Mumbai 400 005, India
Received 19 November 1998 / Accepted 11 January 1999
Abstract
We report on WSRT observations of HI and OH absorption at a
redshift of ![[FORMULA]](img2.gif)
towards the radio lens
PKS 1830-21. The mm wave transitions of several molecular species
have already been observed in absorption towards PKS 1830-21 at
this redshift. At mm wavelengths the source structure is dominated by
two extremely compact components, the northeast (NE) and southwest
(SW) components. At lower frequencies the continuum emission is much
more extended and there is also a broad Einstein ring connecting the
NE and SW components. This larger extent of the continuum means that
the HI and OH spectra sample a much larger region of the absorber than
the mm wave spectra.
The HI spectrum that we obtain is asymmetric, with a peak at
-147 km/s with respect to the main molecular line redshift of
![[FORMULA]](img3.gif)
. Weak mm wave molecular absorption
has also been detected towards the NE component at this same velocity.
The HI absorption, however, covers a total velocity width of
300 km/sec, including velocities well to the red of the deep
molecular features, and is fully resolved suggesting that it is
spatially widespread. In OH we detect both the 1667 and the
1665 MHz transitions, and the velocity-integrated ratio of their
optical depths is consistent with what is expected in thermal
equilibrium. The OH spectrum has a velocity width comparable to that
of the HI spectrum, suggesting that it too is widespread in the
absorber. The lack of a prominent HI peak in the spectrum at the
velocity corresponding to the SW component, suggests that the galaxy
responsible for the absorption at has
a central molecular disk many kpc in size, and that HI may be
deficient in this central region.
Our observations are sensitive to the large scale kinematics of the absorber, and to first order the implied dynamical mass is consistent with the lens models of Nair et al. (1993). Higher spatial resolution is however critical in order to better constrain the lensing models.
Key words: cosmology:
observations 
galaxies:
abundances
radio lines:
ISM
ISM: abundances
Send offprint requests to: Jayaram N. Chengalur
Contents
© European Southern Observatory (ESO) 1999
Online publication: March 1, 1999
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