Galactic Fountains and Gas Accretion

Marinacci, Federico; Binney, James; Fraternali, Filippo; Nipoti, Carlo; Ciotti, Luca; Londrillo, P.; Debattista, Victor P.; Popescu, C. C.

doi:10.1063/1.3458477

Cited by 109 publications

(177 citation statements)

References 5 publications

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“…This process slows down the rotation of the Galactic fountain clouds and produces gas accretion towards the disk. Hydrodynamical simulations show that the Galactic corona could be the reservoir of this accreting gas (Marinacci et al 2010a). The typical orbits of this "accreting Galactic fountain" differ from those of a fountain without accretion for the presence of inward radial motions (Fig.…”

Section: Discussionmentioning

confidence: 99%

Modelling the H i halo of the Milky Way

Marasco

Fraternali

2010

A&A

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Aims. We studied the global distribution and kinematics of the extra-planar neutral gas in the Milky Way.Methods. We built 3D models for a series of Galactic H i layers, projected them for an inside view, and compared them with the Leiden-Argentina-Bonn 21-cm observations. Results. We show that the Milky Way disk is surrounded by an extended halo of neutral gas with a vertical scale-height of 1.6 +0.6 −0.4 kpc and an H i mass of 3.2 +1.0 −0.9 × 10 8 M , which is ∼5−10% of the total Galactic H i. This H i halo rotates more slowly than the disk with a vertical velocity gradient of −15 ± 4 km s −1 kpc −1 . We found evidence for a global infall motion in the halo, both vertical (20 +5 −7 km s −1 ) and radial (30 +7 −5 km s −1 ). Conclusions.The Milky Way H i extra-planar layer shows properties similar to the halos of external galaxies, which is compatible with it being predominantly produced by supernova explosions in the disk. It is most likely composed of distinct gas complexes with masses of ∼10 4−5 M , of which the intermediate velocity clouds are the local manifestations. The classical high-velocity clouds appear to be a separate population.

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Section: Discussionmentioning

confidence: 99%

Modelling the H i halo of the Milky Way

Marasco

Fraternali

2010

A&A

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“…However, according to e.g. Marinacci et al (2010), this galactic fountain gas would be needed to create Kelvin-Helmholtz instabilities in the hot corona such that (hot) gas can condense to clouds that are able to reach the disk. With the presence of supernovae, star-forming galaxies can accumulate enough cold gas to sustain their observed star formation rates (see also Hopkins et al 2008) while in early-type galaxies, like NGC 1167, the creation of instabilities in the halo is prevented (due to the absence of galactic fountains).…”

Section: The Absence Of An H I Halomentioning

confidence: 99%

Cold gas in massive early-type galaxies: the case of NGC 1167

Struve

Oosterloo

Sancisi

et al. 2010

A&A

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We present a study of the morphology and kinematics of the neutral hydrogen in the gas-rich (M HI = 1.5 × 10 10 M ), massive earlytype galaxy NGC 1167, which was observed with the Westerbork Synthesis Radio Telescope (WSRT). The H i is located in a 160 kpc disk (≈3 × D 25 ) and has low surface density (≤2 M pc −2 ). The disk shows regular rotation for r < 65 kpc but several signs of recent and ongoing interaction and merging with fairly massive companions are observed. No population of cold gas clouds is observed -in contrast to what is found in some spiral galaxies. This suggests that currently the main mechanism bringing in cold gas to the disk is the accretion of fairly massive satellite galaxies, rather than the accretion of a large number of small gas clumps. NGC 1167 is located in a (gas-) rich environment: we detect eight companions with a total H i mass of ∼6 × 10 9 M within a projected distance of 350 kpc. Deep optical images show a disrupted satellite at the northern edge of the H i disk. The observed rotation curve shows a prominent bump of about 50 km s −1 (in the plane of the disk) at r ≈ 1.3 × R 25 . This feature in the rotation curve occurs at the radius where the H i surface density drops significantly and may be due to large-scale streaming motions in the disk. We suspect that both the streaming motions and the H i density distribution are the result of the interaction/accretion with the disrupted satellite. Like in other galaxies with wiggles and bumps in the rotation curve, H i scaling describes the observed rotation curve best. We suggest that interactions create streaming motions and features in the H i density distribution and that this is the reason for the success of H i scaling in fitting such rotation curves.

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“…The dominant mode of accretion at the star forming component of a galaxy remains to be determined. The interplay between enriched outflowing gas with gas coming in may be key in this process (Fraternali & Binney, 2008;Putman et al, 2012;Marinacci et al, 2010;Voit et al, 2015).…”

Section: Expected Modes Of Accretionmentioning

confidence: 99%

An Introduction to Gas Accretion onto Galaxies

Putman¹

2017

Astrophysics and Space Science Library

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Evidence for gas accretion onto galaxies can be found throughout the universe. In this chapter, I summarize the direct and indirect signatures of this process and discuss the primary sources. The evidence for gas accretion includes the star formation rates and metallicities of galaxies, the evolution of the cold gas content of the universe with time, numerous indirect indicators for individual galaxies, and a few direct detections of inflow. The primary sources of gas accretion are the intergalactic medium, satellite gas and feedback material. There is support for each of these sources from observations and simulations, but the methods with which the fuel ultimately settles in to form stars remain murky.

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Galactic Fountains and Gas Accretion

Cited by 109 publications

References 5 publications

Modelling the H i halo of the Milky Way

Modelling the H i halo of the Milky Way

Cold gas in massive early-type galaxies: the case of NGC 1167

An Introduction to Gas Accretion onto Galaxies

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