64 research outputs found
Orthogonal vertical velocity dispersion distributions produced by bars
In barred galaxies, the contours of stellar velocity dispersions ()
are generally expected to be oval and aligned with the orientation of bars.
However, many double-barred (S2B) galaxies exhibit distinct peaks on
the minor axis of inner bars, which we termed "-humps," while two local
minima are present close to the ends of inner bars, i.e.,
"-hollows." Analysis of numerical simulations shows that
-humps or hollows should play an important role in generating the
observed -humps+hollows in low-inclination galaxies. In order to
systematically investigate the properties of in barred galaxies, we
apply the vertical Jeans equation to a group of well-designed three-dimensional
bar+disk(+bulge) models. A vertically thin bar can lower along the
bar and enhance it perpendicular to the bar, thus generating
-humps+hollows. Such a result suggests that -humps+hollows
can be generated by the purely dynamical response of stars in the presence of
a, sufficiently massive, vertically thin bar, even without an outer bar. Using
self-consistent -body simulations, we verify the existence of vertically
thin bars in the nuclear-barred and S2B models which generate prominent
-humps+hollows. Thus the ubiquitous presence of -humps+hollows
in S2Bs implies that inner bars are vertically thin. The addition of a bulge
makes the -humps more ambiguous and thus tends to somewhat hide the
-humps+hollows. We show that may be used as a kinematic
diagnostic of stellar components that have different thickness, providing a
direct perspective on the morphology and thickness of nearly face-on bars and
bulges with integral field unit spectroscopy.Comment: 14 pages, 16 figures. Accepted for publication in Ap
Galaxies with multiple bars : constraints on their formation scenarios
Much of current astrophysical research is aimed at addressing one key issue:
how galaxies form and evolve. We still do not fully understand the evolutionary
processes driving the lifetimes of the zoo of galaxies which populate the
Universe. Galaxies may be isolated, or in groups or clusters; they may appear
as pure ellipsoids or discs or include a variety of structures; they may be forming
stars violently or passing quietly through their lives; and the many other properties
that we are progressively discovering. Each piece we add to the puzzle
pile complicates the picture a bit more. This thesis is aimed at fixing one of
these pieces, a specific one related to the very interesting, but so far not well
characterised, double-barred galaxies.
Barred galaxies are rather common structures in the Universe and, more
importantly, they are key elements for secular evolution theories. In fact, bars
can transport gas to the central regions of galaxies and trigger the formation
of bulges and other new structures. Double bars go a step farther: they allow
the material to reach the very central regions where the gas driven inwards by
a single bar cannot get to. Therefore, nested bar systems are considered a very
efficient way to bring about the internal secular evolution of galaxies and even
to feed active galactic nuclei. This hypothesis has, however, some detractors,
as it is very promising from a theoretical point of view but there is not much
observational evidence that it is valid.
In this thesis we have carefully observed and studied a sample of five doublebarred
galaxies using the state-of-the-art techniques for the analysis of their
kinematics and stellar populations. This has led to original work not previously
performed, so each result is relevant and provides clues to the nature
of these objects. We are pleased to present the discovery of the σ-hollows, the
only known kinematical signature of the presence of stellar inner bars. Moreover,
we disentangle the complex structural composition of the galaxies of our
sample, dealing with different formation scenarios and rejecting those which do
not account for the observational properties derived here. We find out that one out of the five galaxies is probably hosting a disc-like bulge, whereas the
other four present a classical bulge in their centres. Finally, we ascertain that
inner bars tend to be younger and more metal-rich than the outer structures.
Nevertheless, the characteristic stellar populations for the bulge and the inner
bar are indistinguishable and there is no evidence of star-forming structures in
the central regions of these galaxies, so we have to conclude that these five inner
bars are not playing a major role in the secular evolution of their host galaxiesGran parte de la investigación astrofÃsica actual gira en torno a una única e
importante cuestión: cómo se forman y evolucionan las galaxias. TodavÃa hoy
no comprendemos los procesos evolutivos que dirigen la vida de ese zoo de
objetos que puebla el Universo. Las galaxias pueden estar aisladas o viviendo
en grupos o cúmulos; pueden aparentar ser simple elipsoides o discos o estar
constituidas por variedad de estructuras; pueden formar estrellas violentamente
o dejar pasar tranquilamente sus vidas; y un largo etcétera de propiedades que
vamos descubriendo poco a poco. Cada pieza que añadimos al puzle complica
la imagen final un poco más. Esta tesis pretende colocar por fin una de esas
piezas, aquella relacionada con el fascinante, aunque todavÃa poco estudiado,
caso de las galaxias con dos barras.
Las galaxias con barra son estructuras comunes en el Universo y elementos
clave en las teorÃas de evolución secular, puesto que las barras son capaces de
transportar gas a las regiones centrales y, por lo tanto, promover la formación
de bulbos y otras estructuras. Las dobles barras van un paso más allá al permitir
que el material alcance las partes más internas de las galaxias, donde el
gas transportado por una barra simple no puede llegar. Es por tanto lógico que
estos sistemas dobles sean considerados fundamentales y muy eficientes para la
evolución secular interna de las galaxias, e incluso se les relaciona a menudo con
los núcleos activos galácticos. Esta hipótesis encuentra, sin embargo, varios detractores,
pues aunque es muy prometedora desde un punto de vista puramente
teórico, no hay evidencias observacionales que la sustenten.
En la presente tesis hemos observado y estudiado en detalle una muestra
de cinco galaxias con dos barras y hemos hecho uso de las técnicas de análisis
más novedosas con el objetivo de caracterizar su cinemática y poblaciones estelares.
Se trata de un trabajo completamente original jamás antes realizado,
por lo que cada resultado es relevante y proporciona nuevas pistas sobre la
naturaleza de estos objetos. Asà pues, presentamos el descubrimiento de los
llamados σ-hollows, las únicas señales cinemáticas conocidas de la presencia de barras internas. Desentrañamos también la compleja composición estructural
de las galaxias de nuestra muestra, considerando los diferentes escenarios
de formación posibles y rechazando aquellos que no explican las propiedades
observacionales encontradas. Obtenemos asà que una de las cinco galaxias en
estudio probablemente contiene un bulbo tipo disco, mientras que el resto de la
muestra está compuesta por bulbos clásicos. Finalmente, averiguamos que las
barras internas tienden a ser más jóvenes y metálicas que las estructuras externas;
sin embargo, las poblaciones estelares caracterÃsticas para el bulbo y la
barra interna son indistinguibles y no hay evidencias de formación estelar relevante
en las regiones centrales, por lo que concluimos que al menos estas cinco
barras internas no están desempeñando un papel importante en la evolución
secular de sus galaxias anfitrionas
Superdense massive galaxies in the Nearby Universe
Superdense massive galaxies (r_e~1 kpc; M~10^{11} Msun) were common in the
early universe (z>1.5). Within some hierarchical merging scenarios, a
non-negligible fraction (1-10%) of these galaxies is expected to survive since
that epoch retaining their compactness and presenting old stellar populations
in the present universe. Using the NYU Value-Added Galaxy Catalog from the SDSS
Data Release 6 we find only a tiny fraction of galaxies (~0.03%) with r_e<1.5
kpc and M_*>8x10^{10} Msun in the local Universe (z<0.2). Surprinsingly, they
are relatively young (~2 Gyr) and metal-rich ([Z/H]~0.2). The consequences of
these findings within the current two competing size evolution scenarios for
the most massive galaxies ("dry" mergers vs "puffing up" due to quasar
activity) are discussed.Comment: Accepted for publication in ApJ Letters; 3 figure
The universal variability of the stellar initial mass function probed by the TIMER survey
The debate about the universality of the stellar initial mass function (IMF) revolves around two competing lines of evidence. While measurements in the Milky Way, an archetypal spiral galaxy, seem to support an invariant IMF, the observed properties of massive early-type galaxies (ETGs) favor an IMF somehow sensitive to the local star-formation conditions. However, the fundamental methodological and physical differences between the two approaches have hampered a comprehensive understanding of IMF variations. Here, we describe an improved modeling scheme that, for the first time, allows consistent IMF measurements across stellar populations with different ages and complex star-formation histories (SFHs). Making use of the exquisite MUSE optical data from the TIMER survey and powered by the MILES stellar population models, we show the age, metallicity, [Mg/Fe], and IMF slope maps of the inner regions of NGC 3351, a spiral galaxy with a mass similar to that of the Milky Way. The measured IMF values in NGC 3351 follow the expectations from a Milky Way-like IMF, although they simultaneously show systematic and spatially coherent variations, particularly for low-mass stars. In addition, our stellar population analysis reveals the presence of metal-poor and Mg-enhanced star-forming regions that appear to be predominantly enriched by the stellar ejecta of core-collapse supernovae. Our findings therefore showcase the potential of detailed studies of young stellar populations to provide the means to better understand the early stages of galaxy evolution and, in particular, the origin of the observed IMF variations beyond and within the Milky Way
Towards a new classification of galaxies: principal component analysis of CALIFA circular velocity curves
We present a galaxy classification system for 238 (E1-Sdm) CALIFA (Calar Alto
Legacy Integral Field Area) galaxies based on the shapes and amplitudes of
their circular velocity curves (CVCs). We infer the CVCs from the de-projected
surface brightness of the galaxies, after scaling by a constant mass-to-light
ratio based on stellar dynamics - solving axisymmetric Jeans equations via
fitting the second velocity moment of
the stellar kinematics. We use principal component analysis (PCA) applied to
the CVC shapes to find characteristic features and use a -means classifier
to separate circular curves into classes. This objective classification method
identifies four different classes, which we name slow-rising (SR), flat (FL),
round-peaked (RP) and sharp-peaked (SP) circular curves.
SR are typical for low-mass, late-type (Sb-Sdm), young, faint, metal-poor and
disc-dominated galaxies. SP are typical for high-mass, early-type (E1-E7), old,
bright, metal-rich and bulge-dominated galaxies. FL and RP appear presented by
galaxies with intermediate mass, age, luminosity, metallicity, bulge-to-disk
ratio and morphologies (E4-S0a, Sa-Sbc). The discrepancy mass factor,
, have the largest value for SR and SP classes ( 74
per cent and 71 per cent, respectively) in contrast to the FL and RP
classes (with 59 per cent and 61 per cent, respectively).
Circular curve classification presents an alternative to typical morphological
classification and appears more tightly linked to galaxy evolution.Comment: Accepted for publication in MNRAS (Minor changes), 123 pages, 19
figures, 87 Tables (containing the basic properties of the 238 E1-Sdm
galaxies; the five main Principal Component Eigenvectors; the five main
Principal Components - PC_i; the Multi-Gaussian Expansion models - MGEs; the
circular velocity curve models and their uncertainties
Disc galaxies are still settling: The discovery of the smallest nuclear discs and their young stellar bars
When galactic discs settle and become massive enough, they are able to form
stellar bars. These non-axisymmetric structures induce shocks in the gas,
causing it to flow to the centre where nuclear structures, such as nuclear
discs and rings, are formed. Previous theoretical and observational studies
have hinted at the co-evolution of bars and nuclear discs, suggesting that
nuclear discs grow "inside-out", thereby proposing that smaller discs live in
younger bars. Nevertheless, it remains unclear how the bar and the nuclear
structures form and evolve with time. The smallest nuclear discs discovered to
date tend to be larger than , even though some theoretical
studies find that when nuclear discs form they can be much smaller. Using MUSE
archival data, we report for the first time two extragalactic nuclear discs
with radius sizes below . Additionally, our estimations reveal the
youngest bars found to date. We estimate that the bars in these galaxies formed
and
ago, for NGC\,289
and NGC\,1566, respectively. This suggests that at least some disc galaxies in
the Local Universe may still be dynamically settling. By adding these results
to previous findings in the literature, we retrieve a stronger correlation
between nuclear disc size and bar length and we derive a tentative exponential
growth scenario for nuclear discs.Comment: Accepted in A&A (in press), 13 pages, 5 figures, 2 tabel
Clocking the assembly of double-barred galaxies with the MUSE TIMER project
The formation of two stellar bars within a galaxy has proved challenging for numerical studies. It is not yet clear whether the inner bar is born via a star formation process promoted by gas inflow along the outer bar or whether it is dynamically assembled from instabilities in a small-scale stellar disc. Observational constraints to these scenarios are scarce. We present a thorough study of the stellar content of two double-barred galaxies observed by the MUSE TIMER project, NGC 1291 and NGC 5850, combined with a two-dimensional multicomponent photometric decomposition performed on the 3.6 μμm images from S^4G. Our analysis confirms the presence of σ-hollows appearing in the stellar velocity dispersion distribution at the ends of the inner bars. Both galaxies host inner discs matching in size with the inner bars, suggestive of a dynamical formation for the inner bars from small-scale discs. The analysis of the star formation histories for the structural components shaping the galaxies provides constraints on the epoch of dynamical assembly of the inner bars, which took place >6.5 Gyr ago for NGC 1291 and >4.5 Gyr ago for NGC 5850. This implies that inner bars are long-lived structures
- …