Extra-planar HI in the Inner Milky Way

2004

Multi-wavelength observations of nearby spiral galaxies have shown that neutral and ionized gas are present up to a few kpc from the disk and that star formation and supernovae probably play an important role in bringing gas into the halo. We have obtained very sensitive H i observations of the face-on galaxy NGC 6946 and of the nearly edge-on starburst galaxy NGC 253. We find high velocity H i clouds in NGC 6946 and extra-planar gas with anomalous velocities in NGC 253. In both galaxies there seems to be a close connection between the star-forming disk and the halo H i. In the outer parts of NGC 6946 there is also evidence for recent gas accretion.

2000

The results of observational studies on the vertical HI density distribution and kinematics of the disks of spiral galaxies are reported and discussed. Attention is drawn to the presence of HI emission, unknown before and here referred to as the 'beard', which has anomalous structure and kinematics, different from the known cold HI disk. This component is extended and probably located in the halo region, it is rotating more slowly than the disk and shows radial inward motion. Its nature and origin −galactic fountain or infall of primordial gas?− are still a puzzle.

The Astrophysical Journal, 1986

2012

Two compact HI clouds which seem to belong to the Ophiuchus superbubble were studied at ∼30

resolution using the Very Large Array (VLA) in C and D configurations together with the Green Bank Telescope (GBT) providing the short-spacing flux. Here we present preliminary results of the data analysis.

Astronomy and Astrophysics, 2005

We report the discovery of a large H  cloud in the central regions of the Virgo cluster. It is 110 × 25 kpc in size and contains 3.4 × 10 8 M ⊙ of H . The morphology and kinematics of this cloud strongly suggest that it consists of H  removed from the galaxy NGC 4388 by ram-pressure stripping. It is more likely the result of an interaction of the ISM of NGC 4388 with the hot halo of the M86 group and not with the ICM centred on M87. The large extent of the plume suggests that gas stripped from cluster galaxies can remain neutral for at least 10 8 yr. Locally, the column density is well above 10 20 cm −2 , suggesting that the intra-cluster H  regions known to exist in Virgo may have formed from gas stripped from cluster galaxies. The existence of the H  plume suggests that stripping of infalling spirals contributes to the enrichment of the ICM. The H  object in the Virgo cluster recently reported by Minchin et al. may have a similar origin and may therefore not be a "dark galaxy".

The Astrophysical Journal, 2006

We have used new and archival infrared and radio observations to search for a dwarf galaxy associated with the high-velocity cloud (HVC) known as Complex H. Complex H is a large (Ω 400 deg 2) and probably nearby (d = 27 kpc) HVC whose location in the Galactic plane has hampered previous investigations of its stellar content. The H I mass of the cloud is 2.0 × 10 7 (d/27 kpc) 2 M ⊙ , making Complex H one of the most massive HVCs if its distance is more than ∼ 20 kpc. Virtually all similar H I clouds in other galaxy groups are associated with low surface brightness dwarf galaxies. We selected mid-infrared sources observed by the MSX satellite in the direction of Complex H that appeared likely to be star-forming regions and observed them at the wavelength of the CO J = 1 → 0 rotational transition in order to determine their velocities. 59 of the 60 observed sources show emission at Milky Way velocities, and we detected no emission at velocities consistent with that of Complex H. We use these observations to set an upper limit on the ongoing star formation rate in the HVC of 5 × 10 −4 M ⊙ yr −1. We also searched the 2MASS database for evidence of any dwarf-galaxy-like stellar population in the direction of the HVC and found no trace of a distant red giant population, with an upper limit on the stellar mass of ∼ 10 6 M ⊙. Given the lack of evidence for either current star formation or an evolved population, we conclude that Complex H cannot be a dwarf galaxy with properties similar to those of known dwarfs. Complex H is therefore one of the most massive known H I clouds that does not contain any stars. If Complex H is self-gravitating, then this object is one of the few known dark galaxy candidates. These findings may offer observational support for the idea that the Cold Dark Matter substructure problem is related to the difficulty of forming stars in low-mass dark matter halos; alternatively, Complex H could be an example of a cold accretion flow onto the Milky Way.

Astronomy and Astrophysics, 2004

We present NOT optical observations of a clump (l = 127. • 9435 , b = +1. • 8298), embedded in an extended, irregularly shaped, diffuse optical nebula. This condensation shows an emission-line spectrum typical of classic H ii regions. Although its location on the sky coincides with a nearby extended photoionized region recently identified by in radio data from the Canadian Galactic Plane Survey (CGPS), the systemic velocity of this ≈ 1 ′ -sized H ii region, VLSR = −71±12 km s −1 , poses it far out in the Galaxy, beyond the Perseus arm. The location of this region in the Galaxy is supported by H i structures visible at comparable radial velocity on CGPS data. We argue that this H ii region might belong to an outer Galactic arm. The emission line ratios of the surrounding extended nebula, whose radial velocity is consistent with that of the small H ii region, are typical of photoionized gas in the low density limit. Smaller clumps of comparable surface brightness are visible within the optical boundaries of the extended, faint nebula. After comparison of the optical data with far infrared and radio observations, we conclude that this nebula is an H ii region, ∼ 70 pc in size, probably photoionized by an association of OB stars and surrounded by a ring of neutral hydrogen.

The Astronomical Journal, 1995

We report the serendipitous discovery of a large HI cloud with an associated HI mass of 6(±1.5) × 10 9 h −2 M ⊙ and a heliocentric velocity 8800 km s −1 , located near the periphery of the cluster of galaxies Abell 2634. Its velocity field appears to be very quiescent, as no gradients in the peak velocity are seen over its extent of 143h −1 by 103h −1 kpc. The distribution of gas is poorly resolved spatially, and it is thus difficult at this time to ascertain the nature of the cloud. At least two relatively small, actively star-forming galaxies appear to be embedded in the HI gas, which may (a) be an extended gaseous envelope surrounding one or both galaxies, (b) have been spread over a large region by a severe episode of tidal disruption or (c) have been affected by the ram pressure resulting from its motion through the intracluster gas of A2634.

The Astrophysical Journal, 2004

Green Bank Telescope (GBT) λ21cm observations have revealed a faint, yet extensive H I cloud population surrounding the Andromeda Galaxy (M31). The newfound objects are likely analogs to the high-velocity H I clouds (HVCs) seen around the Milky Way. At least 20 discrete features are detected within 50 kpc of the M31 disk, with radial velocities that are comparable to those of outer disk rotation. In addition, a filamentary "halo" component of at least 30 kpc extent is concentrated at the M31 systemic velocity. Some of the discrete features are organized into elongated systems with velocity continuity, suggestive of tidal streams. The discrete population can be characterized by a steep power-law distribution of number versus H I mass in the range between 10 5 and 10 7 M ⊙. The velocity line-width of discrete clouds is correlated with the cloud H I mass: such that if the clouds are gravitationally bound this implies a dark-to H I mass ratio of ∼ 100:1. Possible origins for the discrete and "halo" M31 features include: a Local Group "cooling flow", tidal debris from recent mergers or interactions, and the gaseous counterparts of low mass dark-matter halos.

Monthly Notices of the Royal Astronomical Society: Letters, 2005

We present a new scenario in which massive intragroup HI clouds are the highdensity parts of large HI rings/arcs formed by dynamical interaction between galaxy groups and gas-rich, low surface brightness (LSB) galaxies with extended gas disks. Our hydrodynamical simulations demonstrate that the group tidal field is very efficient at stripping the outer HI gas of the disk if the gaseous disk of the LSB galaxy extends 2 − 5 times further than the stellar disk. We find that a massive, extended 'leading stream' orbiting the group's center can form out of the stripped outer HI envelope, while the severely shrunk LSB galaxy, whose stellar disk remains unaffected, continues on its path. The result is a relatively isolated, massive HI cloud with a ring-or arclike shape, a very inhomogeneous density distribution (N HI ∼ 1.0 × 10 17 − 1.1 × 10 20 atoms cm −2 ), and, initially, no stellar content. Only the high density peaks of the simulated intragroup HI ring/arc can be detected in many current HI observations. These will appear as relatively isolated 'HI islands' near the group center. We also find that star formation can occur within the ring/arc, if the total gas mass within the intragroup ring/arc is very large (∼ 4 × 10 9 M ⊙ ). We discuss these results in terms of existing observations of intragroup gas (e.g., the Leo Ring and HIPASS J0731-69) and intergalactic HII regions.