Astronomy & Astrophysics

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Issue		A&A Volume 432, Number 1, March II 2005
Page(s)		45 - 67
Section		Extragalactic astronomy
DOI		10.1051/0004-6361:20040321

A&A 432, 45-67 (2005)
DOI: 10.1051/0004-6361:20040321

The Parkes H I Survey of the Magellanic System

C. Brüns¹, J. Kerp¹, L. Staveley-Smith², U. Mebold¹, M. E. Putman³, R. F. Haynes², P. M. W. Kalberla¹, E. Muller⁴ and M. D. Filipovic^{2, 5}

¹ Radioastronomisches Institut, Universität Bonn, Auf dem Hügel 71, 53121 Bonn, Germany
e-mail: cbruens@astro.uni-bonn.de
² Australia Telescope National Facility, CSIRO, PO Box 76, Epping NSW 1710, Australia
³ Department of Astronomy, University of Michigan, Ann Arbor, MI 48109, USA
⁴ Arecibo Observatory, HC3 Box 53995, Arecibo, PR 00612, USA
⁵ University of Western Sydney, Locked Bag 1797, Penrith South, DC, NSW 1797, Australia

(Received 24 February 2004 / Accepted 27 October 2004)

Abstract
We present the first fully and uniformly sampled, spatially complete $\ion$ survey of the entire Magellanic System with high velocity resolution ( $\Delta v = 1.0$ km s ^-1), performed with the Parkes Telescope. Approximately 24 percent of the southern sky was covered by this survey on a $\approx$ 5´ grid with an angular resolution of ${\it HPBW} = 14\farcm1$ . A fully automated data-reduction scheme was developed for this survey to handle the large number of $\ion$ spectra ( $1.5\times10^6$ ). The individual Hanning smoothed and polarization averaged spectra have an rms brightness temperature noise of $\sigma$ = 0.12 K. The final data-cubes have an rms noise of $\sigma_{\rm rms} \approx 0.05$ K and an effective angular resolution of $\approx$ 16´. In this paper we describe the survey parameters, the data-reduction and the general distribution of the $\ion$ gas. The Large Magellanic Cloud ( LMC ) and the Small Magellanic Cloud ( SMC ) are associated with huge gaseous features - the Magellanic Bridge , the Interface Region , the Magellanic Stream , and the Leading Arm - with a total $\ion$ mass of M( $\ion$ ) = $4.87\times10^8~M_\odot \left[d/55~{\rm kpc}\right]^2$ , if all $\ion$ gas is at the same distance of 55 kpc. Approximately two thirds of this $\ion$ gas is located close to the Magellanic Clouds ( Magellanic Bridge and Interface Region ), and 25% of the $\ion$ gas is associated with the Magellanic Stream . The Leading Arm has a four times lower $\ion$ mass than the Magellanic Stream , corresponding to 6% of the total $\ion$ mass of the gaseous features. We have analyzed the velocity field of the Magellanic Clouds and their neighborhood introducing a LMC-standard-of-rest frame. The $\ion$ in the Magellanic Bridge shows low velocities relative to the Magellanic Clouds suggesting an almost parallel motion, while the gas in the Interface Region has significantly higher relative velocities indicating that this gas is leaving the Magellanic Bridge building up a new section of the Magellanic Stream . The Leading Arm is connected to the Magellanic Bridge close to an extended arm of the LMC . The clouds in the Magellanic Stream and the Leading Arm show significant differences, both in the column density distribution and in the shapes of the line profiles. The $\ion$ gas in the Magellanic Stream is more smoothly distributed than the gas in the Leading Arm . These morphological differences can be explained if the Leading Arm is at considerably lower z-heights and embedded in a higher pressure ambient medium.

Key words: Magellanic Clouds -- galaxies: interactions -- ISM: structure -- ISM: kinematics and dynamics -- surveys

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