26 research outputs found
Interpreting the possible break in the Black Hole - Bulge mass relation
Recent inspections of local available data suggest that the almost linear
relation between the stellar mass of spheroids () and the mass of
the super massive Black Holes (BHs) residing at their centres, shows a break
below , with a steeper, about
quadratic relation at smaller masses. We investigate the physical mechanisms
responsible for the change in slope of this relation, by comparing data with
the results of the semi-analytic model of galaxy formation MORGANA, which
already predicted such a break in its original formulation. We find that the
change of slope is mostly induced by effective stellar feedback in star-forming
bulges. The shape of the relation is instead quite insensitive to other
physical mechanisms connected to BH accretion such as disc instabilities,
galaxy mergers, Active Galactic Nucleus (AGN) feedback, or even the exact
modelling of accretion onto the BH, direct or through a reservoir of low
angular momentum gas. Our results support a scenario where most stars form in
the disc component of galaxies and are carried to bulges through mergers and
disc instabilities, while accretion onto BHs is connected to star formation in
the spheroidal component. Therefore, a model of stellar feedback that produces
stronger outflows in star-forming bulges than in discs will naturally produce a
break in the scaling relation. Our results point to a form of co-evolution
especially at lower masses, below the putative break, mainly driven by stellar
feedback rather than AGN feedback.Comment: MNRAS accepted, 10 pages, 6 figures, 1 tabl
On the shape and evolution of a cosmic ray regulated galaxy-wide stellar initial mass function
In this paper, we present a new derivation of the shape and evolution of the
integrated galaxy-wide initial mass function (IGIMF), incorporating explicitly
the effects of cosmic rays (CRs) as regulators of the chemical and thermal
state of the gas in the dense cores of molecular clouds. We predict the shape
of the IGIMF as a function of star formation rate (SFR) and CR density, and
show that it can be significantly different with respect to local estimates. In
particular, we focus on the physical conditions corresponding to IGIMF shapes
that are simultaneously shallower at high-mass end and steeper at the low-mass
end than a Kroupa IMF. These solutions can explain both the levels of
-enrichment and the excess of low-mass stars as a function of stellar
mass, observed for local spheroidal galaxies. As a preliminary test of our
scenario, we use idealized star formation histories to estimate the mean IMF
shape for galaxies of different stellar mass. We show that the fraction
of low-mass stars as a function of galaxy stellar mass predicted by these mean
IMFs agrees with the values derived from high-resolution spectroscopic surveys.Comment: 8 pages, 5 figures, MNRAS accepte
Development of a multi-payload 2U CubeSat: the Alba project
Alba CubeSat UniPD is a student team of University of Padova with the aim to participate to the ESA Fly Your Satellite! (FYS!) programme and to launch for the first time at University of Padova a CubeSat made by students.
The proposed mission has three independent objectives: (1) to collect in-situ measurements of the sub-mm space debris environment in LEO, (2) to study the micro-vibration environment on the satellite throughout different mission phases, (3) to do precise orbit determination through laser ranging and evaluate procedures for fast satellite Pointing, Acquisition and Tracking (PAT) from ground. The proposed technological experiments aim to obtain data that will enrich the current knowledge of the space environment and will provide precious information useful for the further development of some research projects currently performed at University of Padova.
In order to reach the objectives, in these years the activities of the teams aimed to develop a 2U CubeSat equipped with three payloads. The first payload is an impact sensor that will be placed on one of the outer faces of the satellite and will be able to count the number of debris impacting the spacecraft thus being able to measure the energy/momentum transferred to the satellite. The second one is a Commercial Off The Shelf (COTS) sensor that measures the micro-vibrations experienced by payloads in a CubeSat in different mission phases. The third one consists in a number of COTS Corner Cube Retroreflectors that will be placed onboard the satellite. Thanks to this, Satellite Laser Ranging (SLR) will be done to collect data on the satellite range and range rate using a facility currently under development at University.
This paper presents the mission objectives and motivations. In addition, the mission phases and the preliminary design of the CubeSat reached during the activities of the project are shown. Particular attention is given to the payloads which are the most challenging aspect of this project
Environmental dependence of bulge-dominated galaxy sizes in hierarchical models of galaxy formation. Comparison with the local Universe
We compare state-of-the-art semi-analytic models of galaxy formation as well
as advanced sub-halo abundance matching models with a large sample of
early-type galaxies from SDSS at z < 0.3. We focus our attention on the
dependence of median sizes of central galaxies on host halo mass. The data do
not show any difference in the structural properties of early-type galaxies
with environment, at fixed stellar mass. All hierarchical models considered in
this work instead tend to predict a moderate to strong environmental
dependence, with the median size increasing by a factor of about 1.5-3 when
moving from low to high mass host haloes. At face value the discrepancy with
the data is highly significant, especially at the cluster scale, for haloes
above log Mhalo > 14. The convolution with (correlated) observational errors
reduces some of the tension. Despite the observational uncertainties, the data
tend to disfavour hierarchical models characterized by a relevant contribution
of disc instabilities to the formation of spheroids, strong gas dissipation in
(major) mergers, short dynamical friction timescales, and very short quenching
timescales in infalling satellites. We also discuss a variety of additional
related issues, such as the slope and scatter in the local size-stellar mass
relation, the fraction of gas in local early-type galaxies, and the general
predictions on satellite galaxies.Comment: 27 pages, 14 figures, 2 tables. MNRAS, in pres
The Probabilistic Random Forest applied to the selection of quasar candidates in the QUBRICS Survey
The number of known, bright () QSOs in the
Southern Hemisphere is considerably lower than the corresponding number in the
Northern Hemisphere due to the lack of multi-wavelength surveys at .
Recent works, such as the QUBRICS survey, successfully identified new,
high-redshift QSOs in the South by means of a machine learning approach applied
on a large photometric dataset. Building on the success of QUBRICS, we present
a new QSO selection method based on the Probabilistic Random Forest (PRF), an
improvement of the classic Random Forest algorithm. The PRF takes into account
measurement errors, treating input data as probability distribution functions:
this allows us to obtain better accuracy and a robust predictive model. We
applied the PRF to the same photometric dataset used in QUBRICS, based on the
SkyMapper DR1, Gaia DR2, 2MASS, WISE and GALEX databases. The resulting
candidate list includes sources with . We estimate for our proposed
algorithm a completeness of and a purity of on the test
datasets. Preliminary spectroscopic campaigns allowed us to observe 41
candidates, of which 29 turned out to be QSOs. The performances of the
PRF, currently comparable to those of the CCA, are expected to improve as the
number of high-z QSOs available for the training sample grows: results are
however already promising, despite this being one of the first applications of
this method to an astrophysical context.Comment: Accepted for publication in MNRAS, 12 pages, 11 figures, 4 table
The Rise of Active Galactic Nuclei in the GAlaxy Evolution and Assembly semi-analytic model
We present a new implementation of the GAlaxy Evolution and Assembly (GAEA)
semi-analytic model, that features an improved modelling of the process of cold
gas accretion onto supermassive black hole (SMBHs), derived from both analytic
arguments and high-resolution simulations. We consider different scenarios for
the loss of angular momentum required for the available cold gas to be accreted
onto the central SMBHs, and we compare different combinations of triggering
mechanisms, including galaxy mergers and disc instabilities in star forming
discs. We compare our predictions with the luminosity function (LF) observed
for Active Galactic Nuclei (AGN) and we confirm that a non-instantaneous
accretion timescale (either in the form of a low-angular momentum reservoir or
as an assumed light curve evolution) is needed in order to reproduce the
measured evolution of the AGN-LF and the so-called AGN-downsizing trend.
Moreover, we also study the impact of AGN feedback, in the form of AGN-driven
outflows, on the SF properties of model galaxies, using prescriptions derived
both from empirical studies or from numerical experiments. We show that
AGN-driven outflows are effective in suppressing the residual star formation
rate in massive galaxies () without changing their overall
assembly history. These winds also affect the SFR of lower mass galaxies,
resulting in a too large fraction of passive galaxies at .
Finally, we study the Eddington ratio distribution as a function of SMBH mass,
showing that only objects more massive than are already in a
self-regulated state as inferred from observations.Comment: 19 pages, 12 figures, 1 table, replaced with MNRAS accepted versio
Spectroscopy of QUBRICS quasar candidates: 1672 new redshifts and a Golden Sample for the Sandage Test of the Redshift Drift
The QUBRICS (QUasars as BRIght beacons for Cosmology in the Southern
hemisphere) survey aims at constructing a sample of the brightest quasars with
z>~2.5, observable with facilities in the Southern Hemisphere. QUBRICS makes
use of the available optical and IR wide-field surveys in the South and of
Machine Learning techniques to produce thousands of bright quasar candidates of
which only a few hundred have been confirmed with follow-up spectroscopy.
Taking advantage of the recent Gaia Data Release 3, which contains 220 million
low-resolution spectra, and of a newly developed spectral energy distribution
fitting technique, designed to combine the photometric information with the
Gaia spectroscopy, it has been possible to measure 1672 new secure redshifts of
QUBRICS candidates, with a typical uncertainty . This
significant progress of QUBRICS brings it closer to (one of) its primary goals:
providing a sample of bright quasars at redshift 2.5 < z < 5 to perform the
Sandage test of the cosmological redshift drift. A Golden Sample of seven
quasars is presented that makes it possible to carry out this experiment in
about 1500 hours of observation in 25 years, using the ANDES spectrograph at
the 39m ELT, a significant improvement with respect to previous estimates.Comment: 11 pages, 10 figures, accepted for publication in MNRA
Probing the roles of orientation and multi-scale gas distributions in shaping the obscuration of Active Galactic Nuclei through cosmic time
The origin of obscuration in Active Galactic Nuclei (AGN) is still an open
debate. In particular, it is unclear what drives the relative contributions to
the line-of-sight column densities from galaxy-scale and torus-linked
obscuration. The latter source is expected to play a significant role in
Unification Models, while the former is thought to be relevant in both
Unification and Evolutionary Models. In this work, we make use of a combination
of cosmological semi-analytic models and semi-empirical prescriptions for the
properties of galaxies and AGN, to study AGN obscuration. We consider a
detailed object-by-object modelling of AGN evolution, including different AGN
light curves (LCs), gas density profiles, and also AGN feedback-induced gas
cavities. Irrespective of our assumptions on specific AGN LC or galaxy gas
fractions, we find that, on the strict assumption of an exponential profile for
the gas component, galaxy-scale obscuration alone can hardly reproduce the
fraction of cm sources at least at
. This requires an additional torus component with a thickness that
decreases with luminosity to match the data. The torus should be present in all
evolutionary stages of a visible AGN to be effective, although galaxy-scale gas
obscuration may be sufficient to reproduce the obscured fraction with cm (Compton-thin, CTN) if we assume extremely compact
gas disc components. The claimed drop of CTN fractions with increasing
luminosity does not appear to be a consequence of AGN feedback, but rather of
gas reservoirs becoming more compact with decreasing stellar mass.Comment: MNRAS, accepted, 19 pages, 15 figures, 3 appendice
Near-infrared spectroscopy of extreme BAL QSOs from the QUBRICS bright quasar survey
We report on the spectral confirmation of 18 QSO candidates from the "QUasars
as BRIght beacons for Cosmology in the Southern hemisphere'' survey (QUBRICS),
previously observed in the optical band, for which we acquired new
spectroscopic data in the near-infrared band with the Folded-port InfraRed
Echellette spectrograph (FIRE) at the Magellan Baade telescope. In most cases,
further observations were prompted by the peculiar nature of the targets, whose
optical spectra displayed unexpected absorption features. All candidates have
been confirmed as bona fide QSOs, with average emission redshift .
The analysis of the emission and absorption features in the spectra, performed
with Astrocook and QSFit, reveals that the large majority of these objects are
broad-absorption line (BAL) QSOs, with almost half of them displaying strong Fe
II absorption (typical of the so-called FeLoBAL QSOs). The detection of such a
large fraction of rare objects (which are estimated to account for less than
one percent of the general QSO population) is interpreted as an unexpected (yet
favourable) consequence of the particular candidate selection procedure adopted
within the QUBRICS survey. The measured properties of FeLoBAL QSOs observed so
far provide no evidence that they are a manifestation of a particular stage in
AGN evolution. In this paper we present an explorative analysis of the
individual QSOs, to serve as a basis for a further, more detailed
investigation
Further constraining galaxy evolution models through the Size Function of SDSS Early-type galaxies
We discuss how the effective radius Phi(Re) function (ERF) recently worked
out by Bernardi et al. (2009) represents a new testbed to improve the current
understanding of Semi-analytic Models of Galaxy formation. In particular, we
here show that a detailed hierarchical model of structure formation can broadly
reproduce the correct peak in the size distribution of local early-type
galaxies, although it significantly overpredicts the number of very compact and
very large galaxies. This in turn is reflected in the predicted size-mass
relation, much flatter than the observed one, due to too large (~3 kpc)
low-mass galaxies (<10^11 \msun), and to a non-negligible fraction of compact
( 10^11 \msun). We also find that the
latter discrepancy is smaller than previously claimed, and limited to only
ultracompact (Re < 0.5 kpc) galaxies when considering elliptical-dominated
samples. We explore several causes behind these effects. We conclude that the
former problem might be linked to the initial conditions, given that large and
low-mass galaxies are present at all epochs in the model. The survival of
compact and massive galaxies might instead be linked to their very old ages and
peculiar merger histories. Overall, knowledge of the galactic stellar mass {\em
and} size distributions allows a better understanding of where and how to
improve models.Comment: 15 pages, 10 Figures. Accepted by MNRA