Alignment of galaxies relative to their local environment in SDSS-DR8

Hirv, A.; Pelt, J.; Saar, E.; Tago, E.; Tamm, A.; Tempel, Elmo; Einasto, M.

doi:10.1051/0004-6361/201629248

Cited by 54 publications

(55 citation statements)

References 96 publications

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“…Our novel predictions for the alignment between virtual galaxies and the cosmic web based on Horizon-AGN are finally also in good agreement with observational results that tend to find disks with a spin lying in the plane of walls and parallel to filaments, as well as ellipticals elongated along filaments and walls implying their spins are instead perpendicular to them (see e.g Lee & Erdogdu 2007;Li et al 2013;Zhang et al 2013;Huang et al 2016;Hirv et al 2017;Lee, Kim & Rey 2018), despite other conflicting 9 The alignment of the shapes (i.e minor axes) with the filaments and walls could also be predicted using a tidal stretching model together with the anisotropy of the cosmic web but this is left for future works. observational results (e.g Varela et al 2012).…”

Section: Resultssupporting

confidence: 87%

Galaxy orientation with the cosmic web across cosmic time

Codis

Jindal

Chisari

et al. 2018

Monthly Notices of the Royal Astronomical Society

120

150

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This work investigates the alignment of galactic spins with the cosmic web across cosmic time using the cosmological hydrodynamical simulation Horizon-AGN. The cosmic web structure is extracted via the persistent skeleton as implemented in the DISPERSE algorithm. It is found that the spin of low-mass galaxies is more likely to be aligned with the filaments of the cosmic web and to lie within the plane of the walls while more massive galaxies tend to have a spin perpendicular to the axis of the filaments and to the walls. The mass transition is detected with a significance of 9 sigmas. This galactic alignment is consistent with the alignment of the spin of dark haloes found in pure dark matter simulations and with predictions from (anisotropic) tidal torque theory. However, unlike haloes, the alignment of low-mass galaxies is weak and disappears at low redshifts while the orthogonal spin orientation of massive galaxies is strong and increases with time, probably as a result of mergers. At fixed mass, alignments are correlated with galaxy morphology: the high-redshift alignment is dominated by spiral galaxies while elliptical centrals are mainly responsible for the perpendicular signal. These predictions for spin alignments with respect to cosmic filaments and unprecendently walls are successfully compared with existing observations. The alignment of the shape of galaxies with the different components of the cosmic web is also investigated. A coherent and stronger signal is found in terms of shape at high mass. The two regimes probed in this work induce competing galactic alignment signals for weak lensing, with opposite redshift and luminosity evolution. Understanding the details of these intrinsic alignments will be key to exploit future major cosmic shear surveys like Euclid or LSST.

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Section: Resultssupporting

confidence: 87%

Galaxy orientation with the cosmic web across cosmic time

Codis

Jindal

Chisari

et al. 2018

Monthly Notices of the Royal Astronomical Society

120

150

View full text Add to dashboard Cite

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“…This result has since been reproduced in multiple cosmological simulations with and without baryons (Hahn et al 2010;Codis et al 2012;Libeskind et al 2013;Trowland et al 2013;Dubois et al 2014;Forero-Romero et al 2014;Wang & Kang 2017). The alignment has been confirmed by observational studies, most outstandingly so in the finding by that massive elliptical galaxies tend to have their spin perpendicular to their host filaments while the spin of less massive bright spirals has a tendency to lie parallel to their host filaments (see also Jones et al 2010;Tempel & Libeskind 2013;Zhang et al 2013Zhang et al , 2015Hirv et al 2017). The transition mass from halo spins preferentially perpendicular to preferentially parallel to their host haloes is known as the spin flip mass.…”

Section: Introductionmentioning

confidence: 57%

The Cosmic Ballet: spin and shape alignments of haloes in the cosmic web

Veena

Cautun

Weygaert

et al. 2018

Monthly Notices of the Royal Astronomical Society

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We investigate the alignment of haloes with the filaments of the cosmic web using an unprecedently large sample of dark matter haloes taken from the P-Millennium ΛCDM cosmological N-body simulation. We use the state-of-the-art NEXUS morphological formalism which, due to its multiscale nature, simultaneously identifies structures at all scales. We find strong and highly significant alignments, with both the major axis of haloes and their peculiar velocity tending to orient along the filament. However, the spin -filament alignment displays a more complex trend changing from preferentially parallel at low masses to preferentially perpendicular at high masses. This "spin flip" occurs at an average mass of 5 × 10 11 h −1 M . This mass increases with increasing filament diameter, varying by more than an order of magnitude between the thinnest and thickest filament samples. We also find that the inner parts of haloes have a spin flip mass that is several times smaller than that of the halo as a whole. These results confirm that recent accretion is responsible for the complex behaviour of the halo spin -filament alignment. Low-mass haloes mainly accrete mass along directions perpendicular to their host filament and thus their spins tend to be oriented along the filaments. In contrast, high-mass haloes mainly accrete along their host filaments and have their spins preferentially perpendicular to them. Furthermore, haloes located in thinner filaments are more likely to accrete along their host filaments than haloes of the same mass located in thicker filaments.

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“…Finally, we try to reconcile this scenario with the previous findings that the spin axes of galaxies are aligned with large-scale filaments. According to recent studies in simulations (Navarro et al 2004;Aragón-Calvo et al 2007;Brunino et al 2007;Cen 2014;Dubois et al 2014;Liu 2017;Lee et al 2018) and in observations (Tempel & Libeskind 2013;Zhang et al 2013Zhang et al , 2015Hirv et al 2017;Kim et al 2018;Jeong et al 2019), late-type galaxies in a filament tend to have spin axes parallel with the filament direction, while spin axes of early-type galaxies tend to be perpendicular to it. Since the galaxies with strong coherence signals in our results may be mainly late-type galaxies, if they are located in filaments, their spin axes may be aligned to be parallel with filaments according to those studies.…”

Section: Discussionmentioning

confidence: 97%

Mysterious Coherence in Several-megaparsec Scales between Galaxy Rotation and Neighbor Motion

Lee

Pak

Song

et al. 2019

ApJ

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In our recent report, observational evidence supports that the rotational direction of a galaxy tends to be coherent with the average motion of its nearby neighbors within 1 Mpc. We extend the investigation to neighbors at farther distances, in order to examine if such dynamical coherence is found even in large scales. The Calar Alto Legacy Integral Field Area (CALIFA) survey data and the NASA-Sloan Atlas (NSA) catalog are used. From the composite map of velocity distribution of 'neighbor' galaxies within 15 Mpc from the CALIFA galaxies, the composite radial profiles of the luminosity-weighted mean velocity of neighbors are derived. These profiles show unexpectedly strong evidence of the dynamical coherence between the rotation of the CALIFA galaxies and the average line-of-sight motion of their neighbors within several Mpc distances. Such a signal is particularly strong when the neighbors are limited to red ones: the luminosity-weighted mean velocity at 1 < D ≤ 6 Mpc is as large as 30.6 ± 10.9 km s −1 (2.8σ significance to random spin-axis uncertainty) for central rotation (R ≤ R e ). In the comparison of several subsamples, the dynamical coherence tends to be marginally stronger for the diffuse or kinematically-well-aligned CALIFA galaxies. For this mysterious coherence in large scales, we cautiously suggest a scenario that it results from a possible relationship between the long-term motion of a large-scale structure and the rotations of galaxies in it.

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Alignment of galaxies relative to their local environment in SDSS-DR8

Cited by 54 publications

References 96 publications

Galaxy orientation with the cosmic web across cosmic time

Galaxy orientation with the cosmic web across cosmic time

The Cosmic Ballet: spin and shape alignments of haloes in the cosmic web

Mysterious Coherence in Several-megaparsec Scales between Galaxy Rotation and Neighbor Motion

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