Metallicity gradients in disks

Pilkington, K.; Few, C. G.; Gibson, Brad K.; Calura, F.; Michel-Dansac, Léo; Thacker, Robert J.; Mollá, M.; Matteuccí, F.; Rahimi, A.; Kawata, Daisuke; Kobayashi, Chiaki; Brook, Chris; Stinson, Greg; Couchman, H. M. P.; Bailin, Jeremy; Wadsley, James

doi:10.1051/0004-6361/201117466

Cited by 202 publications

(268 citation statements)

References 73 publications

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“…From a MWG-like model, we obtained the evolution of the radial gradient of Oxygen abundances, finding a gradient of ∼ −0.2 dex kpc −1 for z = 2 which flattens with time until reaching the present time value ∼ −0.05 − 0.06 dex kpc −1 . This behavior was in agreement with the cosmological simulations from Pilkington et al (2012) and also with the Yuan et al (2011) value found at z ∼ 1.5. However, it is necessary to take into account that this gradient was calculated with the O abundances of all radial regions † Recent works conclude that there are at least two stellar generations in these old objects.…”

Section: Introductionsupporting

confidence: 91%

The evolution of the oxygen abundance radial gradient in the Milky Way Galaxy disk

Mollá¹,

Cavichia

Costa

et al. 2016

Proc. IAU

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Abstract. We review the state of our chemical evolution models for spiral and low mass galaxies. We analyze the consequences of using different stellar yields, infall rate laws and star formation prescriptions in the time/redshift evolution of the radial distributions of abundances, and other quantities as star formation rate or gas densities, in the Milky Way Galaxy; In particular we will study the evolution of the Oxygen abundance radial gradient analyzing its relation with the ratio SFR/infall. We also compare the results with our old chemical evolution models, cosmological simulations and with the existing data, mainly with the planetary nebulae abundances.

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Section: Introductionsupporting

confidence: 91%

The evolution of the oxygen abundance radial gradient in the Milky Way Galaxy disk

Mollá¹,

Cavichia

Costa

et al. 2016

Proc. IAU

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“…This assumption is a natural outcome of the mass, momentum, and energy conservation laws imposed in the simulations of disks in a cosmological context (Brook et al 2011(Brook et al , 2012Few et al 2012;Pilkington et al 2012a,b;Gibson et al 2013). Pilkington et al (2012a) examined a set of 25 simulations, from several groups, using different codes and initial conditions (Stinson et al 2010;Rahimi et al 2011;Kobayashi & Nakasato 2011;Few et al 2012) to predict the present-day metallicity gradient in MW-like galaxies and its evolution. Although the evolution of the simulated metallicity gradients depends strongly on the choice of the subgrid physics employed, most of the simulated galaxies tend to a similar present-day gradient of ∼−0.05 dex kpc −1 , in agreement with the Chiappini et al (2001) and Mollá & Díaz (2005) models for normal galaxies as the MW.…”

Section: Theoretical Predictions From Cosmological Simulationsmentioning

confidence: 99%

“…Recently, a new set of cosmological hydrodynamic simulations have started to predict how the spatially resolved information of the properties of stellar populations in galaxies can constrain the complex interplay between gas infall, outflows, stellar migration, radial gas flows, and star formation efficiency, in driving the inside-out growth of galactic disks (Brook et al 2012;Gibson et al 2013;Few et al 2012;Pilkington et al 2012a;Minchev et al 2014). Radiative cooling, star formation, feedback from supernovae, and chemical enrichment are also included in simulations to predict radial metallicity gradients as a function of merging history.…”

Section: Introductionmentioning

confidence: 99%

The CALIFA survey across the Hubble sequence

Delgado

García-Benito

Pérez

et al. 2015

A&A

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234

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Various different physical processes contribute to the star formation and stellar mass assembly histories of galaxies. One important approach to understanding the significance of these different processes on galaxy evolution is the study of the stellar population content of today's galaxies in a spatially resolved manner. The aim of this paper is to characterize in detail the radial structure of stellar population properties of galaxies in the nearby universe, based on a uniquely large galaxy sample, considering the quality and coverage of the data. The sample under study was drawn from the CALIFA survey and contains 300 galaxies observed with integral field spectroscopy. These cover a wide range of Hubble types, from spheroids to spiral galaxies, while stellar masses range from M ∼ 10 9 to 7 × 10 11 M . We apply the fossil record method based on spectral synthesis techniques to recover the following physical properties for each spatial resolution element in our target galaxies: the stellar mass surface density (µ ), stellar extinction (A V ), light-weighted and mass-weighted ages ( log age L , log age M ), and mass-weighted metallicity ( log Z M ). To study mean trends with overall galaxy properties, the individual radial profiles are stacked in seven bins of galaxy morphology (E, S0, Sa, Sb, Sbc, Sc, and Sd). We confirm that more massive galaxies are more compact, older, more metal rich, and less reddened by dust. Additionally, we find that these trends are preserved spatially with the radial distance to the nucleus. Deviations from these relations appear correlated with Hubble type: earlier types are more compact, older, and more metal rich for a given M , which is evidence that quenching is related to morphology, but not driven by mass. Negative gradients of log age L are consistent with an inside-out growth of galaxies, with the largest log age L gradients in Sb-Sbc galaxies. Further, the mean stellar ages of disks and bulges are correlated and with disks covering a wider range of ages, and late-type spirals hosting younger disks. However, age gradients are only mildly negative or flat beyond R ∼ 2 HLR (half light radius), indicating that star formation is more uniformly distributed or that stellar migration is important at these distances. The gradients in stellar mass surface density depend mostly on stellar mass, in the sense that more massive galaxies are more centrally concentrated. Whatever sets the concentration indices of galaxies obviously depends less on quenching/morphology than on the depth of the potential well. There is a secondary correlation in the sense that at the same M early-type galaxies have steeper gradients. The µ gradients outside 1 HLR show no dependence on Hubble type. We find mildly negative log Z M gradients, which are shallower than predicted from models of galaxy evolution in isolation. In general, metallicity gradients depend on stellar mass, and less on morphology, hinting that metallicity is affected by both -the depth of the potential well and morphology/quenching....

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“…However, a similarly lower [Fe/H] could also be expected if the Head was a remote part of an progenitor disk involving the Body -stellar metallicity gradient determinations (e.g. Pilkington et al 2012;Sánchez-Blázquez et al 2014) are quite noisy, however, and moreover, in that case the Tail would be expected to have a similar lower value, which it does not have.…”

Section: Two or Three Galaxies?mentioning

confidence: 92%

Shutting down or powering up a (U)LIRG? Merger components in distinctly different evolutionary states in IRAS 19115−2124 (the Bird)

Vaïsänen

Reunanen

Kotilainen

et al. 2017

Monthly Notices of the Royal Astronomical Society

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We present new SINFONI near-infrared integral field unit (IFU) spectroscopy and SALT optical long-slit spectroscopy characterising the history of a nearby merging luminous infrared galaxy, dubbed the Bird (IRAS19115-2114). The NIR line-ratio maps of the IFU data-cubes and stellar population fitting of the SALT spectra now allow dating of the star formation (SF) over the triple system uncovered from our previous adaptive optics data. The distinct components separate very clearly in a line-ratio diagnostic diagram. An off-nuclear pure starburst dominates the current SF of the Bird with 60-70% of the total, with a 4-7 Myr age, and signs of a fairly constant long-term star formation of the underlying stellar population. The most massive nucleus, in contrast, is quenched with a starburst age of > 40 Myr and shows hints of budding AGN activity. The secondary massive nucleus is at an intermediate stage. The two major components have a population of older stars, consistent with a starburst triggered 1 Gyr ago in a first encounter. The simplest explanation of the history is that of a triple merger, where the strongly star forming component has joined later. We detect multiple gas flows in different phases. The Bird offers an opportunity to witness multiple stages of galaxy evolution in the same system; triggering as well as quenching of SF, and the early appearance of AGN activity. It also serves as a cautionary note on interpretations of observations with lower spatial resolution and/or without infrared data. At high-redshift the system would look like a clumpy starburst with crucial pieces of its puzzle hidden, in danger of misinterpretations.

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Metallicity gradients in disks

Cited by 202 publications

References 73 publications

The evolution of the oxygen abundance radial gradient in the Milky Way Galaxy disk

The evolution of the oxygen abundance radial gradient in the Milky Way Galaxy disk

The CALIFA survey across the Hubble sequence

Shutting down or powering up a (U)LIRG? Merger components in distinctly different evolutionary states in IRAS 19115−2124 (the Bird)

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