Galaxies���intergalactic medium interaction calculation ��� I. Galaxy formation as a function of large-scale environment

Crain, Robert A.; Theuns, Tom; Vecchia, Claudio Dalla; Eke, V. R.; Frenk, Carlos S.; Jenkins, Adrian; Kay, Scott T.; Peacock, J. A.; Pearce, Frazer R.; Schaye, Joop; Springel, Volker; Thomas, P.; White, Simon D. M.; Wiersma, Robert P. C.

doi:10.1111/j.1365-2966.2009.15402.x

Cited by 250 publications

(324 citation statements)

References 140 publications

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“…The decrease at late times is due to the quenching of SF by lower cooling rates in hotter and lower density gas, in addition to gas exhaustion and self-regulated feedback from stars and black holes. Similar results are provided by, e.g., White and Frenk (1991), Hernquist and Springel (2003), Somerville et al (2008), Crain et al (2009), andChoi andNagamine (2009). Schaye et al (2010) stress that without AGN feedback it is difficult to match the steep decline in the cosmic SFR below z = 2.…”

Section: Star-formation History Of the Universesupporting

confidence: 73%

Star formation sustained by gas accretion

Alméida

Elmegreen

Muñoz–Tuñón

et al. 2014

Astron Astrophys Rev

177

130

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Numerical simulations predict that metal-poor gas accretion from the cosmic web fuels the formation of disk galaxies. This paper discusses how cosmic gas accretion controls star formation, and summarizes the physical properties expected for the cosmic gas accreted by galaxies. The paper also collects observational evidence for gas accretion sustaining star formation. It reviews evidence inferred from neutral and ionized hydrogen, as well as from stars. A number of properties characterizing large samples of star-forming galaxies can be explained by metal-poor gas accretion, in particular, the relationship among stellar mass, metallicity, and star-formation rate (the so-called fundamental metallicity relationship). They are put forward and analyzed. Theory predicts gas accretion to be particularly important at high redshift, so indications based on distant objects are reviewed, including the global star-formation history of the universe, and the gas around galaxies as inferred from absorption features in the spectra of background sources.

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Section: Star-formation History Of the Universesupporting

confidence: 73%

Star formation sustained by gas accretion

Alméida

Elmegreen

Muñoz–Tuñón

et al. 2014

Astron Astrophys Rev

177

130

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“…We also note that sometimes even relatively massive galaxies with a total mass of up to ≈10 11 M are called dwarf galaxies (e.g. Crain et al 2009) in the sense that they have a sub-galactic mass value compared to the typical galactic systems in the present Universe, such as the Milky Way. However, primordial systems of this mass, as well as LBGs, would not have evolved to become the typical LG dIrrs that we investigate in this paper.…”

Section: Magnetization Of the Igmmentioning

confidence: 99%

“…Continuous star formation agrees with the detection of significant amounts of gas in these systems (Mateo 1998). We adopted a higher ambient gas temperature (T IGM = 10 5 K), as the IGM in the LG is not pristine and likely to have a hot component due to galactic feedback, structure formation heating, and the large potential wells of massive spirals (Davé & Oppenheimer 2007;Crain et al 2009). There are also some predictions that the density of the local IGM is about 10 −4 cm −3 (Pildis & McGaugh 1996;Rasmussen et al 2003;Sembach 2006), which we use to estimate the ambient pressure P IGM .…”

Section: Magnetization Of the Igmmentioning

confidence: 99%

Magnetic fields in Local Group dwarf irregulars

Chyży

Weżgowiec

Beck

et al. 2011

A&A

116

150

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Aims. We wish to clarify whether strong magnetic fields can be effectively generated in typically low-mass dwarf galaxies and to assess the role of dwarf galaxies in the magnetization of the Universe. Methods. We performed a search for radio emission and magnetic fields in an unbiased sample of 12 Local Group (LG) irregular and dwarf irregular galaxies with the 100-m Effelsberg telescope at 2.64 GHz. Three galaxies were detected. A higher frequency (4.85 GHz) was used to search for polarized emission in five dwarfs that are the most luminous ones in the infrared domain, of which three were detected. Results. Magnetic fields in LG dwarfs are weak, with a mean value of the total field strength of <4.2 ± 1.8 μG, three times lower than in the normal spirals. The strongest field among all LG dwarfs of 10 μG (at 2.64 GHz) is observed in the starburst dwarf IC 10. The production of total magnetic fields in dwarf systems appears to be regulated mainly by the star-formation surface density (with the power-law exponent of 0.30 ± 0.04) or by the gas surface density (with the exponent 0.47 ± 0.09). In addition, we find systematically stronger fields in objects of higher global star-formation rate. The dwarf galaxies follow a similar far-infrared relationship (with a slope of 0.91 ± 0.08) to that determined for high surface brightness spiral galaxies. The magnetic field strength in dwarf galaxies does not correlate with their maximum rotational velocity, indicating that a small-scale rather than a large-scale dynamo process is responsible for producting magnetic fields in dwarfs. If magnetization of the Universe by galactic outflows is coeval with its metal enrichment, we show that more massive objects (such as Lyman break galaxies) can efficiently magnetize the intergalactic medium with a magnetic field strength of about 0.8 nG out to a distance of 160-530 kpc at redshifts 5-3, respectively. Magnetic fields that are several times weaker and shorter magnetization distances are expected for primordial dwarf galaxies. We also predict that most star-forming local dwarfs might have magnetized their surroundings up to a field strength about 0.1 μG within about a 5 kpc distance. Conclusions. Strong magnetic fields (>6 μG) are observed only in dwarfs of extreme characteristics (e.g. NGC 4449, NGC 1569, and the LG dwarf IC 10). They are all starbursts and more evolved objects of statistically much higher metallicity and global star-formation rate than the majority of the LG dwarf population. Typical LG dwarfs are unsuitable objects for the efficient supply of magnetic fields to the intergalactic medium.

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“…Cold gas is known to play an important role in the formation and evolution of galaxies (Kereš et al 2005;Crain et al 2009;van de Voort et al 2011). Therefore, our understanding of the structure, properties and evolution of galaxies can not be complete without knowing about the various phases of the gas, including atomic hydrogen (H I), in and around galaxies, and their dependence on other galaxy characteristics.…”

Section: Introductionmentioning

confidence: 99%

The Lockman Hole project: gas and galaxy properties from a stacking experiment

Geréb

Morganti

Oosterloo

et al. 2013

A&A

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We perform an H I stacking analysis to study the relation between H I content and optical/radio/IR properties of galaxies located in the Lockman Hole area. In the redshift range covered by the observations (up to z = 0.09), we use the SDSS to separate galaxies with different optical characteristics, and we exploit the deep L-band radio continuum image (with noise 11 μJy beam −1 ) to identify galaxies with radio continuum emission. Infrared properties are extracted from the Spitzer catalog. We detect H I in blue galaxies, but H I is also detected in the group of red galaxies -albeit with smaller amounts than for the blue sample. We identify a group of optically inactive galaxies with early-type morphology that does not reveal any H I and ionized gas. These inactive galaxies likely represent the genuine red and dead galaxies depleted of all gas. Unlike inactive galaxies, H I is detected in red LINER-like objects. Galaxies with radio continuum counterparts mostly belong to the sub-mJy population, whose objects are thought to be a mixture of star-forming galaxies and low-power AGNs. After using several AGN diagnostics, we conclude that the radio emission in the majority of our sub-mJy radio sources stems from star formation. LINERs appear to separate into two groups based on IR properties and H I content. LINERs with a 24 μm detection show relatively large amounts of H I and are also often detected in radio continuum as a result of ongoing star formation. The LINER galaxies which are not detected at 24 μm are more like the optically inactive galaxies by being depleted of H I gas and having no sign of star formation. Radio LINERs in the latter group are the best candidates for hosting low-luminosity radio AGN.

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Galaxies��intergalactic medium interaction calculation �� I. Galaxy formation as a function of large-scale environment

Cited by 250 publications

References 140 publications

Star formation sustained by gas accretion

Star formation sustained by gas accretion

Magnetic fields in Local Group dwarf irregulars

The Lockman Hole project: gas and galaxy properties from a stacking experiment

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Galaxies���intergalactic medium interaction calculation ��� I. Galaxy formation as a function of large-scale environment

Cited by 250 publications

References 140 publications

Star formation sustained by gas accretion

Star formation sustained by gas accretion

Magnetic fields in Local Group dwarf irregulars

The Lockman Hole project: gas and galaxy properties from a stacking experiment

Contact Info

Product

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Galaxies��intergalactic medium interaction calculation �� I. Galaxy formation as a function of large-scale environment