A unified scenario for the origin of spiral and elliptical galaxy structural scaling laws

Ferrero, I.; Navarro, Julio F.; Abadi, Mario G.; Benavides, José Antonio Chacón; Mast, D.

doi:10.1051/0004-6361/202039839

Cited by 14 publications

(10 citation statements)

References 91 publications

(102 reference statements)

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“…Since the galaxy properties change with time, the slope of the FP is expected to change with redshift. This is confirmed by the numerical models of single galaxies, large-scale cosmological simulations, and observational surveys at different redshifts, among others (see Beifiori et al 2017;Rosito et al 2019a,b;Lu et al 2019;Ferrero et al 2021;de Graaff et al 2022 and references therein).…”

Section: Origin Of the Fp And Its Tiltsupporting

confidence: 53%

A new framework for understanding the evolution of early-type galaxies

D'Onofrio¹,

Chiosi²

2023

A&A

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Context. We have recently suggested that the combination of the scalar virial theorem (M s ∝ R e σ 2 ) and the L = L 0 σ β law, with L 0 and β changing from galaxy to galaxy (and with time), can provide a new set of equations valid for investigating the evolution of early-type galaxies. These equations are able to account for the tilt of the fundamental plane and to explain the observed distributions of early-type galaxies in all its projections. Aims. In this paper we analyze the advantages offered by these equations, derive the β and L 0 parameters for real and simulated galaxies, and demonstrate that depending on the value of β galaxies can move only along some permitted directions in the fundamental plane projections. Then we show that simple galaxy models that grow in mass by infall of gas and form stars with a star formation rate depending on the stellar velocity dispersion nicely reproduce the observed distributions of early-type galaxies in the fundamental plane projections and yield βs that agree with the measured values. Methods. We derive the mutual relationships among the stellar mass, effective radius, velocity dispersion, and luminosity of earlytype galaxies as a function of β and calculate the coefficients of the fundamental plane. Then, using the simple infall models, we show that the star formation history of early-type galaxies is compatible with the σ-dependent star formation rate, and that both positive and negative values of β are possible in a standard theory of galaxy evolution. Results. The parameter β(t) offers a new view of the evolution of early-type galaxies. In brief, it gives a coherent interpretation of the fundamental plane and of the motions of galaxies in its projections; it is the fingerprint of their evolution; it measures the degree of virialization of early-type galaxies; and finally it allows us to infer their evolution in the near past.Conclusions.

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Section: Origin Of the Fp And Its Tiltsupporting

confidence: 53%

A new framework for understanding the evolution of early-type galaxies

D'Onofrio¹,

Chiosi²

2023

A&A

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“…We also note that the anisotropy observed at σ > 250 km s −1 when comparing σ 3D and σ 1D or contrasting σ 1D measurements along different axes is unrelated to this offset. Ferrero et al (2021) also show that the M * -σ * relation of the subhalos in TNG100 and EAGLE simulation is offset from the observed relation. They derive the observed relation based on stellar velocity dispersions within effective radii of ∼300 earlytype galaxies included in ATLAS3D (Cappellari et al 2013) and SLACS (Bolton et al 2006) data.…”

Section: The M * -σ * Relation As a Test Of Illustristngmentioning

confidence: 68%

Velocity Dispersions of Quiescent Galaxies in IllustrisTNG

Sohn,

Geller,

Borrow

et al. 2024

ApJ

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We examine the central stellar velocity dispersion of subhalos based on IllustrisTNG cosmological hydrodynamic simulations. The central velocity dispersion is a fundamental observable that links galaxies with their dark matter subhalos. We carefully explore simulated stellar velocity dispersions derived with different definitions to assess possible systematics. We explore the impact of variation in the identification of member stellar particles, the viewing axes, the velocity dispersion computation technique, and simulation resolution. None of these issues impact the velocity dispersion significantly; any systematic uncertainties are smaller than the random error. We examine the stellar mass–velocity dispersion relation as an observational test of the simulations. At fixed stellar mass, the observed velocity dispersions significantly exceed the simulation results. This discrepancy is an interesting benchmark for the IllustrisTNG simulations because the simulations are not explicitly tuned to match this relation. We demonstrate that the stellar velocity dispersion provides measures of the dark matter velocity dispersion and the dark matter subhalo mass.

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“…In our models, the weak dependence of velocity dispersion on 𝐵/𝑇 is just a reflection of the virial theorem -velocity dispersion depends more on the total mass within an aperture and less on how this mass is distributed in it. This may partly explain the similarity in the scaling relations of early and latetype galaxies (e.g., Bernardi et al 2011;Ferrero et al 2021), as well as the universality of the 𝑀 𝑏ℎ − 𝜎 relation (e.g., Ferrarese & Merritt 2000;Shankar et al 2016).…”

Section: The Low Redshift Universementioning

confidence: 94%

“…Velocity dispersion is also a tracer of the distribution of dark matter in the inner regions of the galaxies, via the dynamical mass 𝑀 𝑑𝑦𝑛 (< 𝑅) ∝ 𝑅 𝜎 𝑎 𝑝 (𝑅) 2 , which traces the gravitational influence of the total mass within 𝑅 on test (stellar or gas) particles. The ratio between dynamical and stellar mass within the effective radius, 𝑀 𝑑𝑦𝑛 (< 𝑅 𝑒 )/𝑀 * (< 𝑅 𝑒 ), appears to be increasing with stellar mass, 𝑀 𝑑𝑦𝑛 ∝ 𝑀 * 1+𝛼 , with 𝛼 ∼ 0.2 − 0.3 (e.g., Pahre et al 1998;Padmanabhan et al 2004;Gallazzi et al 2006;Hopkins et al 2009), which is related to the overall "tilt" of the fundamental plane (FP) of galaxies (e.g., Djorgovski & Davis 1987;Dressler et al 1987), where the FP terminology is usually mostly applied to earlier type galaxies (e.g., Bernardi et al 2020, but see also Ferrero et al 2021). Different effects could contribute to the tilt of the FP and more specifically to the slope of the 𝑀 𝑑𝑦𝑛 /𝑀 * ratio, from an increasing contribution of dark matter in larger/more massive galaxies, to the effect of stellar non-homology, radial anisotropy, and/or systematic variations of the stellar population (e.g., Ciotti et al 1996;Trujillo et al 2004;Bertin & Lombardi 2006;Cappellari et al 2006;Hyde & Bernardi 2009;Hopkins et al 2009;Cappellari et al 2013;D'Onofrio et al 2013;Zahid et al 2016;Zahid & Geller 2017;Bernardi et al 2020;Mould 2020;D'Eugenio et al 2021).…”

Section: Introductionmentioning

confidence: 99%

The weak dependence of velocity dispersion on disc fractions, mass-to-light ratio, and redshift: implications for galaxy and black hole evolution

Marsden

Shankar

Bernardi

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Velocity dispersion (σ) is a key driver for galaxy structure and evolution. We here present a comprehensive semi-empirical approach to compute σ via detailed Jeans modelling assuming both a constant and scale-dependent mass-to-light ratio M*/L. We compare with a large sample of local galaxies from MaNGA and find that both models can reproduce the Faber-Jackson (FJ) relation and the weak dependence of σ on bulge-to-total ratio B/T (for B/T ≳ 0.25). The dynamical-to-stellar mass ratio within R ≲ Re can be fully accounted for by a gradient in M*/L. We then build velocity dispersion evolutionary tracks σap[M*, z] (within an aperture) along the main progenitor dark matter haloes assigning stellar masses, effective radii and Sérsic indices via a variety of abundance matching and empirically motivated relations. We find: 1) clear evidence for downsizing in σap[M*, z] along the progenitor tracks; 2) at fixed stellar mass σ∝(1 + z)0.2 − 0.3 depending on the presence or not of a gradient in M*/L. We extract σap[M*, z] from the TNG50 hydrodynamic simulation and find very similar results to our models with constant M*/L. The increasing dark matter fraction within Re tends to flatten the σap[M*, z] along the progenitors at z ≳ 1 in constant M*/L models, while σap[M*, z] have a steeper evolution in the presence of a stellar gradient. We then show that a combination of mergers and gas accretion are likely responsible for the constant or increasing σap[M*, z] with time. Finally, our σap[M*, z] are consistent with a nearly constant and steep Mbh − σ relation at z ≲ 2, with black hole masses derived from the LX − M* relation.

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A unified scenario for the origin of spiral and elliptical galaxy structural scaling laws

Cited by 14 publications

References 91 publications

A new framework for understanding the evolution of early-type galaxies

A new framework for understanding the evolution of early-type galaxies

Velocity Dispersions of Quiescent Galaxies in IllustrisTNG

The weak dependence of velocity dispersion on disc fractions, mass-to-light ratio, and redshift: implications for galaxy and black hole evolution

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