Astronomical Science The Magellanic Stream — A Tail of Two Galaxies Andrew J. Fox 1 pull gas out of their potential wells and 90 Philipp Richter 2 create the Stream (e.g., Besla et al., b l Bart P. Wakker 3 2010). In the ram-pressure model, drag Nicolas Lehner 4 forces exerted on the LMC and SMC –40 60 4 J. Christopher Howk as they pass through the extended gase­ NGC 7469 Joss Bland-Hawthorn 5 ous halo of the Galaxy push gas out of –50 their interstellar medium into the wake of their orbits (e.g., Mastropietro et al., 2005). NGC 7714 1 Space Telescope Science Institute, –60 Baltimore, USA The Stream is split spatially into two 2 University of Potsdam, Germany principal filaments, which appear to wrap 3 University of Wisconsin­Madison, USA around each other, and is paired with –70 PHL 2525 4 University of Notre Dame, USA a “Leading Arm” of material extending for 30 5 University of Sydney, Australia ~ 60 degrees on the other side of the LMC and SMC. Since the Leading Arm lies in front of the direction of motion of –80 Interactions between spiral galaxies the LMC and SMC, it cannot be created –80–70 and their dwarf satellites are often spec- by ram­pressure forces, so at least this 0 tacular, producing extended streams portion of the Magellanic System is –80 HE 0056–3622 of stripped gas and triggering new gen- thought to be tidally created. However, if erations of star formation. The most the entire Stream were created by tidal striking local example lies in the outer forces, there ought to be a stellar compo­ 330 halo of the Milky Way in the form of nent, yet such a stellar stream has never –70 the Magellanic Stream. Extending for been observed, despite deep searches. RBS 144 over 140 degrees, the Stream is a giant Both origin mechanisms may therefore be ribbon of gas trailing the orbit of the at play. –60 Fairall 9 Large and Small Magellanic Clouds. Since its discovery over 40 years ago, the Stream has puzzled observers Studying the Stream in absorption –50 SMC and theorists alike and raised many questions. New spectroscopic obser- While the radio data give exquisite quality –40 300 vations with the Hubble Space Tele- maps of the neutral gas in the Stream, LMC scope and VLT/UVES are addressing absorption­line spectroscopy of back­ these questions and finding the origin of ground targets is needed to reveal how 270 l the Stream to be surprisingly complex. much ionised gas and metal enrichment is present. Using ultraviolet (UV) spectra Figure 1. H I 21 cm map of the Magellanic Stream taken with the Cosmic Origins Spectro­ generated from the Leiden/Argentine/Bonn (LAB) survey, colour­coded by H I column density (from Fox Discovery of the Magellanic Stream graph (COS) on board the Hubble Space et al., 2013). The map is shown in Galactic coordi­ Telescope (HST), together with optical nates centred on the South Galactic Pole, with the Radio observations in the early 1970s spectra from VLT/UVES, we recently stud­ LMC and SMC at the bottom. Background sources are indicated with stars. RBS 144 and Fairall 9 sam­ discovered an extended stream of H I ied 14 active galactic nuclei (AGN) lying ple the two principal filaments of the Stream. 21­cm­emitting neutral gas emanating behind or near the Stream (a map of the from the Magellanic Clouds and passing Stream is shown in Figure 1, with the over a wide swath of the southern sky positions of several of the AGN marked). Fairall 9. This indicates that complex sub­ (Dieter, 1971; Wannier & Wrixon, 1972). The resonance lines of the key elements structure and fragmentation is present Dubbed the Magellanic Stream, this for interstellar abundance measurements in the gas. This substructure provides a object has been studied extensively with all lie in the UV, so the COS observations valuable template for modelling the UV successive generations of sensitive radio are necessary for constraining the lines observed at lower resolution with telescopes (e.g., Putman et al., 2003; Stream’s metallicity. However, the UVES COS (20 km s–1 FWHM). Brüns et al., 2005), and has been the observations have the advantage of high subject of many simulations exploring its velocity resolution (4.0 km s–1 full width The Stream’s metallicity was derived in existence and properties. The nature at half maximum [FWHM] given the each direction by comparing the strength of the mechanism(s) producing the 0.6-arcsecond slit used), which allows of the O I 1302 Å, S II 1250 Å or S II 1259 Å Stream is still debated; the two leading the component structure of the cool gas UV ab sorption lines to the strength of the theories are tidal stripping and ram-­ in the Stream to be resolved. An example H I (atomic hydrogen) 21 cm emission line pressure stripping. In the tidal scenario, of the UVES data is shown in Figure 2, measured from radio telescope obser­ gravitational forces exerted by the Large in which seven components of Ca II H and vations. Neutral oxygen (O I) and singly Magellanic Cloud (LMC) and the Small K absorption are seen in the velocity ionised sulphur (S II) are chosen for these Magellanic Cloud (SMC) on each other interval of the Stream toward the AGN measurements since, in interstellar envi­ 28 The Messenger 153 – September 2013 1!2 ' (& 22 * BL ( ! ' BL& 22 (( 3 2 ".2 * * ! ' ( 3" /@QJDR ! 3 3 BL 2H (( "@ ((h l l l l l l 5+21JLR 5+21JLR %@HQ@KK "@ ((h TW ' (BL& 22 2 ((".2 Ck -@ (h * -NQL@KHRD ! 3 -@ (h l l l l l l 5+21JLR 5+21JLR 3H ((h Figure 3. UV and radio spectra used to derive the Fortunately, information on the metallicity metallicity of the Magellanic Stream towards RBS 5 JLRl evolution of the Magellanic Clouds is +21 144 (upper) and Fairall 9 (lower), two directions that available from their age–metallicity rela­ lie only 8.4 degrees apart on the sky, yet trace two Figure 2. High­resolution VLT/UVES spectra of Ca II, tions (Pagel & Tautvaisiene, 1998); these separate filaments of the Stream. The shaded Na I, and Ti II absorption lines in the direction of Fairall indicate that 2 Gyr ago, the SMC abun­ regions show the Stream component, with the Milky 9 (from Richter et al., 2013). Magellanic Stream –1 dance was ~ 10% Solar, matching the Way component visible near 0 km s . The abun­ absorption is visible in multiple components at local dance of sulphur in the Stream is only 10% Solar standard of rest (LSR) velocities between +130 and value we measure in the Stream, whereas toward RBS 144, but 50% Solar toward Fairall 9. +240 km s–1. The red lines indicate our Voigt-profile fit the mean LMC abundance at that time to the data. In the top panel, the Galactic All Sky Sur­ was much higher, at ~ 30–40% Solar. vey (GASS) 21 cm profile is included for comparison. Our results thus support a scenario in which lies close to the Magellanic Clouds which most of the Stream was stripped on the sky, the sulphur abundance in ronments, they are largely unaffected by from the SMC (not the LMC), and has the Stream is found to be 50% solar (Fig­ ionisation and dust­depletion effects, so not self­enriched since its formation, ure 3 lower panels), five times higher than their ratios with H I provide robust metal­ because there is no evidence for ongoing the value measured in the other direc­ licity indicators. We found the Stream’s star formation in the gas. In a sense, we tions, and much higher than expected for metallicity to be only ≈ 10% of the Solar have measured a fossil record of the gas that has been stripped from the SMC. value in three separate directions sam­ Stream at the time of its birth in the SMC Furthermore, the Fairall 9 direction traces pling most of its length (Fox et al., 2010; about 2 Gyr ago. a filament of the Stream that appears to 2013; see Figure 3 upper panels), consid­ connect kinematically to the southeastern erably lower than the current­day average corner of the LMC (Nidever et al., 2008). metallicity of the SMC (≈ 20% Solar) and A second filament connected to the Our measurement of a higher metal abun­ the LMC (≈ 50% Solar). However, the age LMC? dance in this direction supports this of the Stream is estimated from tidal claim, and points towards a dual origin models to be around 2 Gyr (e.g., Besla et However, a fourth sightline we studied for the Stream, with two interwoven al., 2010), and to determine its parent gal­ (toward the AGN Fairall 9) tells a very strands of material, one pulled out of the axy, we need to know the LMC and SMC different story (Richter et al., 2013; see SMC ~ 2 Gyr ago and another pulled out metallicity at that time in the past. also Gibson et al., 2000). In this direction, of the LMC more recently. The Messenger 153 – September 2013 29 Astronomical Science Fox A. J. et al., The Magellanic Stream — A Tail of Two Galaxies In both strands of the Stream, we meas­ reach the disc, or evaporate into the neutral phase, the eventual fate of the ure a low nitrogen abundance relative to million­degree corona? Continued star Stream may be to feed the halo, not the sulphur: in the LMC filament toward Fair­ formation in spiral galaxies like the Milky disc, of our Galaxy.