Gas loss in simulated galaxies as they fall into clusters

Cen, Renyue; Pop, Ana-Roxana; Bahcall, Neta A.

doi:10.1073/pnas.1407300111

Cited by 28 publications

(24 citation statements)

References 59 publications

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“…Therefore, we conclude that our observations are consistent with the expectations of ram-pressure stripping. Our results demonstrate that during infall, the hot gas content of such groups is efficiently stripped already at these large distances from the cluster core, in agreement with the recent simulations of Cen et al (2014).…”

Section: Ram-pressure Stripping Propertiessupporting

confidence: 91%

The stripping of a galaxy group diving into the massive cluster A2142

Eckert

Molendi

Owers

et al. 2014

A&A

105

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Structure formation in the current Universe operates through the accretion of group-scale systems onto massive clusters. The detection and study of such accreting systems is crucial to understand the build-up of the most massive virialized structures we see today. We report the discovery with XMM-Newton of an irregular X-ray substructure in the outskirts of the massive galaxy cluster Abell 2142. The tip of the X-ray emission coincides with a concentration of galaxies. The bulk of the X-ray emission of this substructure appears to be lagging behind the galaxies and extends over a projected scale of at least 800 kpc. The temperature of the gas in this region is 1.4 keV, which is a factor of ∼4 lower than the surrounding medium and is typical of the virialized plasma of a galaxy group with a mass of a few 10 13 M . For this reason, we interpret this structure as a galaxy group in the process of being accreted onto the main dark-matter halo. The X-ray structure trailing behind the group is due to gas stripped from its original dark-matter halo as it moves through the intracluster medium (ICM). This is the longest X-ray trail reported to date. For an infall velocity of ∼1200 km s −1 we estimate that the stripped gas has been surviving in the presence of the hot ICM for at least 600 Myr, which exceeds the Spitzer conduction timescale in the medium by a factor of 400. Such a strong suppression of conductivity is likely related to a tangled magnetic field with small coherence length and to plasma microinstabilities. The long survival time of the low-entropy intragroup medium suggests that the infalling material can eventually settle within the core of the main cluster.

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Section: Ram-pressure Stripping Propertiessupporting

confidence: 91%

The stripping of a galaxy group diving into the massive cluster A2142

Eckert

Molendi

Owers

et al. 2014

A&A

105

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“…18, where the fraction of late-type galaxies with a quenching factor QF > 0.8 and an HI-deficiency HI − de f > 0.4 are plotted versus the distance from the core of the Virgo cluster. Figure 18 clearly shows that both fractions drop by a factor of 5 from the core of the cluster (R/R vir < 0.5), where the hot X-ray gas is detected by ROSAT (Bohringer et al 1994), to the cluster periphery (R/R vir > ∼ 4), in agreement with models and simulations (Tonnesen et al 2007;Bahe et al 2013;Cen et al 2014). Recent observations of nearby clusters with 4−8 m class telescopes equipped with wide-field panoramic detectors and narrow-band filters revealed several star forming galaxies with long tails of ionised gas that are typically produced by a ram-pressure-stripping event up to the cluster virial radius Sun et al 2007;Yagi et al 2010;Fossati et al 2012).…”

Section: Identification Of the Perturbing Mechanismsupporting

confidence: 72%

Quenching of the star formation activity in cluster galaxies

Boselli

Roehlly

Fossati

et al. 2016

A&A

112

155

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We study the star formation quenching mechanism in cluster galaxies by fitting the spectral energy distribution (SED) of the Herschel Reference Survey, a complete volume-limited K-band-selected sample of nearby galaxies including objects in different density regions, from the core of the Virgo cluster to the general field. The SEDs of the target galaxies were fitted using the CIGALE SED modelling code. The truncated activity of cluster galaxies was parametrised using a specific star formation history with two free parameters, the quenching age QA and the quenching factor QF. These two parameters are crucial for the identification of the quenching mechanism, which acts on long timescales when starvation processes are at work, but is rapid and efficient when ram pressure occurs. To be sensitive to an abrupt and recent variation of the star formation activity, we combined twenty photometric bands in the UV to far-infrared in a new way with three age-sensitive Balmer line absorption indices extracted from available medium-resolution (R ∼ 1000) integrated spectroscopy and with Hα narrow-band imaging data. The use of a truncated star formation history significantly increases the quality of the fit in HI-deficient galaxies of the sample, that is to say, in those objects whose atomic gas content has been removed during the interaction with the hostile cluster environment. The typical quenching age of the perturbed late-type galaxies is QA < ∼ 300 Myr whenever the activity of star formation is reduced by 50% < QF ≤ 80% and QA < ∼ 500 Myr for QF > 80%, while that of the quiescent early-type objects is QA 1−3 Gyr. The fraction of late-type galaxies with a star formation activity reduced by QF > 80% and with an HI-deficiency parameter HI − de f > 0.4 drops by a factor of ∼5 from the inner half virial radius of the Virgo cluster (R/R vir < 0.5), where the hot diffuse X-ray emitting gas of the cluster is located, to the outer regions (R/R vir > 4). The efficient quenching of the star formation activity observed in Virgo suggests that the dominant stripping process is ram pressure. We discuss the implication of this result in the cosmological context of galaxy evolution.

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“…Recent hydrodynamic simulations demonstrate that the fraction of gas-rich galaxies steadily declines from the field to the cluster center (Cen et al 2014). A possible auxiliary effect comes from AGN heating through radio jets that keeps the intracluster medium from condensing onto galaxies.…”

Section: Discussionmentioning

confidence: 99%

Changing Ionization Conditions in SDSS Galaxies With Active Galactic Nuclei as a Function of Environment From Pairs to Clusters

Khabiboulline

Steinhardt

Silverman

et al. 2014

ApJ

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We study how active galactic nucleus (AGN) activity changes across environments from galaxy pairs to clusters using 143,843 galaxies with z < 0.2 from the Sloan Digital Sky Survey. Using a refined technique, we apply a continuous measure of AGN activity, characteristic of the ionization state of the narrow-line emitting gas. Changes in key emission-line ratios ([N ii] λ6548/Hα, [O iii] λ5007/Hβ) between different samples allow us to disentangle different environmental effects while removing contamination. We confirm that galaxy interactions enhance AGN activity. However, conditions in the central regions of clusters are inhospitable for AGN activity even if galaxies are in pairs. These results can be explained through models of gas dynamics in which pair interactions stimulate the transfer of gas to the nucleus and clusters suppress gas availability for accretion onto the central black hole.

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Gas loss in simulated galaxies as they fall into clusters

Cited by 28 publications

References 59 publications

The stripping of a galaxy group diving into the massive cluster A2142

The stripping of a galaxy group diving into the massive cluster A2142

Quenching of the star formation activity in cluster galaxies

Changing Ionization Conditions in SDSS Galaxies With Active Galactic Nuclei as a Function of Environment From Pairs to Clusters

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