26 research outputs found
Starbursts driven by central gas compaction
Starburst (SB) galaxies are a rare population of galaxies with star formation
rates (SFRs) greatly exceeding those of the majority of star-forming galaxies
with similar stellar mass. It is unclear whether these bursts are the result of
either especially large gas reservoirs or enhanced efficiencies in converting
gas into stars. Tidal torques resulting from gas-rich galaxy mergers are known
to enhance the SFR by funneling gas towards the centre. However, recent
theoretical works show that mergers do not always trigger a SB and not all SB
galaxies are interacting systems, raising the question of what drives a SB. We
analyse a large sample of SB galaxies and a mass- and redshift-matched sample
of control galaxies, drawn from the FIREbox cosmological volume at z=0-1. We
find that SB galaxies have both larger molecular gas fractions and shorter
molecular depletion times than control galaxies, but similar total gas masses.
Control galaxies evolve towards the SB regime by gas compaction in their
central regions, over timescales of about 70 Myr, accompanied by an increase in
the fraction of ultra-dense and molecular gas. The driving mechanism behind the
SB varies depending on the mass of the galaxy. Massive (Mstar > 1e10 Msun)
galaxies undergoing intense, long-lasting SBs are mostly driven by galaxy
interactions. Conversely, SBs in non-interacting galaxies are often triggered
by a global gravitational instability, that can result in a breathing mode in
low-mass galaxies.Comment: 21 pages, 18 figures, submitted to MNRA
Starburst-induced gas-stars kinematic misalignment
A kinematic misalignment of the stellar and gas components is a phenomenon
observed in a significant fraction of galaxies. However, the underlying
physical mechanisms are not well understood. A commonly proposed scenario for
the formation of a misaligned component requires any pre-existing gas disc to
be removed, via fly-bys or ejective feedback from an active galactic nucleus.
In this Letter, we study the evolution of a Milky Way mass galaxy in the
FIREbox cosmological volume that displays a thin, counter-rotating gas disc
with respect to its stellar component at low redshift. In contrast to scenarios
involving gas ejection, we find that pre-existing gas is mainly removed via the
conversion into stars in a central starburst, triggered by a merging satellite
galaxy. The newly-accreted, counter-rotating gas eventually settles into a
kinematically misaligned disc. About 4.4 (8 out of 182) of FIREbox galaxies
with stellar masses larger than 5e9 Msun at z=0 exhibit gas-star kinematic
misalignment. In all cases, we identify central starburst-driven depletion as
the main reason for the removal of the pre-existing co-rotating gas component,
with no need for feedback from, e.g., a central active black hole. However,
during the starburst, the gas is funneled towards the central regions, likely
enhancing black hole activity. By comparing the fraction of misaligned discs
between FIREbox and other simulations and observations, we conclude that this
channel might have a non-negligible role in inducing kinematic misalignment in
galaxies.Comment: 9 pages; 3 figures; submitted to ApJ Letter
Realistic H i scale heights of Milky Way-mass galaxies in the FIREbox cosmological volume
Accurately reproducing the thin cold gas discs observed in nearby spiral galaxies has been a long standing issue in cosmological simulations. Here, we present measurements of the radially resolved H i scale height in 22 non-interacting Milky Way-mass galaxies from the FIREbox cosmological volume. We measure the H i scale heights using five different approaches commonly used in the literature: fitting the vertical volume density distribution with a Gaussian, the distance between maximum and half-maximum of the vertical volume density distribution, a semi-empirical description using the velocity dispersion and the galactic gravitational potential, the analytic assumption of hydrostatic equilibrium, and the distance from the midplane which encloses ≳60 per cent of the H i mass. We find median H i scale heights, measured using the vertical volume distribution, that range from ∼100 pc in the galactic centres to ∼800 pc in the outskirts and are in excellent agreement with recent observational results. We speculate that the presence of a realistic multiphase interstellar medium, including cold gas, and realistic stellar feedback are the drivers behind the realistic H i scale heights
The WISDOM of power spectra: how the galactic gravitational potential impacts a galaxy’s central gas reservoir in simulations and observations
Observations indicate that the central gas discs are smoother in early-type galaxies than their late-type counterparts, while recent simulations predict that the dynamical suppression of star formation in spheroid-dominated galaxies is preceded by the suppression of fragmentation of their interstellar media. The mass surface density power spectrum is a powerful tool to constrain the degree of structure within a gas reservoir. Specifically here, we focus on the power spectrum slope and aim to constrain whether the shear induced by a dominant spheroidal potential can induce sufficient turbulence to suppress fragmentation, resulting in the smooth central gas discs observed. We compute surface density power spectra for the nuclear gas reservoirs of fourteen simulated isolated galaxies and twelve galaxies observed as part of the mm-Wave Interferometric Survey of Dark Object Masses (WISDOM) project. Both simulated and observed galaxies range from disc-dominated galaxies to spheroids, with central stellar mass surface densities, a measure of bulge dominance, varying by more than an order of magnitude. For the simulations, the power spectra steepen with increasing central stellar mass surface density, thereby clearly linking the suppression of fragmentation to the shear-driven turbulence induced by the spheroid. The WISDOM observations show a different (but potentially consistent) picture: while there is no correlation between the power spectrum slopes and the central stellar mass surface densities, the slopes scatter around a value of 2.6. This is similar to the behaviour of the slopes of the simulated galaxies with high central stellar mass surface densities, and could indicate that high shear eventually drives incompressible turbulence
WISDOM Project - XVI. The link between circumnuclear molecular gas reservoirs and active galactic nucleus fuelling
We use high-resolution data from the millimetre-Wave Interferometric Survey of Dark Object Masses (WISDOM) project to investigate the connection between circumnuclear gas reservoirs and nuclear activity in a sample of nearby galaxies. Our sample spans a wide range of nuclear activity types including radio galaxies, Seyfert galaxies, low-luminosity active galactic nuclei (AGN) and inactive galaxies. We use measurements of nuclear millimetre continuum emission along with other archival tracers of AGN accretion/activity to investigate previous claims that at, circumnuclear scales (<100 pc), these should correlate with the mass of the cold molecular gas. We find that the molecular gas mass does not correlate with any tracer of nuclear activity. This suggests the level of nuclear activity cannot solely be regulated by the amount of cold gas around the supermassive black hole (SMBH). This indicates that AGN fuelling, that drives gas from the large-scale galaxy to the nuclear regions, is not a ubiquitous process and may vary between AGN type, with time-scale variations likely to be very important. By studying the structure of the central molecular gas reservoirs, we find our galaxies have a range of nuclear molecular gas concentrations. This could indicate that some of our galaxies may have had their circumnuclear regions impacted by AGN feedback, even though they currently have low nuclear activity. Alternatively, the nuclear molecular gas concentrations in our galaxies could instead be set by secular processes
WISDOM Project -- XV. Giant Molecular Clouds in the Central Region of the Barred Spiral Galaxy NGC 5806
We present high spatial resolution ( pc) Atacama Large
Millimeter/sub-millimeter Array CO(2-1) observations of the central
region of the nearby barred spiral galaxy NGC 5806. NGC 5806 has a highly
structured molecular gas distribution with a clear nucleus, a nuclear ring and
offset dust lanes. We identify spatially- and spectrally-resolved giant
molecular clouds (GMCs). These clouds have comparable sizes ()
and larger gas masses, observed linewidths () and
gas mass surface densities than those of clouds in the Milky Way disc. The size
-- linewidth relation of the clouds is one of the steepest reported so far
(), the clouds are on
average only marginally bound (with a mean virial parameter
), and high velocity dispersions
are observed in the nuclear ring. These behaviours are likely due to bar-driven
gas shocks and inflows along the offset dust lanes, and we infer an inflow
velocity of kms and a total molecular gas mass inflow rate
of M yr into the nuclear ring. The observed internal
velocity gradients of the clouds are consistent with internal turbulence. The
number of clouds in the nuclear ring decreases with azimuthal angle downstream
from the dust lanes without clear variation of cloud properties. This is likely
due to the estimated short lifetime of the clouds ( Myr), which
appears to be mainly regulated by cloud-cloud collision and/or shear processes.
Overall, it thus seems that the presence of the large-scale bar and gas inflows
to the centre of NGC 5806 affect cloud properties.Comment: Accepted for publication in MNRAS, 20 pages, 16 figure
HI discs of L galaxies as probes of the baryonic physics of galaxy evolution
Understanding what shapes the cold gas component of galaxies, which both
provides the fuel for star formation and is strongly affected by the subsequent
stellar feedback, is a crucial step towards a better understanding of galaxy
evolution. Here, we analyse the HI properties of a sample of 46 Milky Way
halo-mass galaxies, drawn from cosmological simulations (EMP-Pathfinder and
FIREbox). This set of simulations comprises galaxies evolved self-consistently
across cosmic time with different baryonic sub-grid physics: three different
star formation models [constant star formation efficiency (SFE) with different
star formation eligibility criteria, and an environmentally-dependent,
turbulence-based SFE] and two different feedback prescriptions, where only one
sub-sample includes early stellar feedback. We use these simulations to assess
the impact of different baryonic physics on the HI content of galaxies. We find
that the galaxy-wide HI properties agree with each other and with observations.
However, differences appear for small-scale properties. The thin HI discs
observed in the local Universe are only reproduced with a turbulence-dependent
SFE and/or early stellar feedback. Furthermore, we find that the morphology of
HI discs is particularly sensitive to the different physics models: galaxies
simulated with a turbulence-based SFE have discs that are smoother and more
rotationally symmetric, compared to those simulated with a constant SFE;
galaxies simulated with early stellar feedback have more regular discs than
supernova-feedback-only galaxies. We find that the rotational asymmetry of the
HI discs depends most strongly on the underlying physics model, making this a
promising observable for understanding the physics responsible for shaping the
interstellar medium of galaxies.Comment: 13 pages, 10 figures + appendices (7 pages, 10 figures); updated to
version accepted by MNRA
The WISDOM of power spectra: how the galactic gravitational potential impacts a galaxy?s central gas reservoir in simulations and observations
Observations indicate that the central gas discs are smoother in early-type galaxies than their late-type counterparts, while recent simulations predict that the dynamical suppression of star formation in spheroid-dominated galaxies is preceded by the suppression of fragmentation of their interstellar media. The mass surface density power spectrum is a powerful tool to constrain the degree of structure within a gas reservoir. Specifically here, we focus on the power spectrum slope and aim to constrain whether the shear induced by a dominant spheroidal potential can induce sufficient turbulence to suppress fragmentation, resulting in the smooth central gas discs observed. We compute surface density power spectra for the nuclear gas reservoirs of fourteen simulated isolated galaxies and twelve galaxies observed as part of the mm-Wave Interferometric Survey of Dark Object Masses (WISDOM) project. Both simulated and observed galaxies range from disc-dominated galaxies to spheroids, with central stellar mass surface densities, a measure of bulge dominance, varying by more than an order of magnitude. For the simulations, the power spectra steepen with increasing central stellar mass surface density, thereby clearly linking the suppression of fragmentation to the shear-driven turbulence induced by the spheroid. The WISDOM observations show a different (but potentially consistent) picture: while there is no correlation between the power spectrum slopes and the central stellar mass surface densities, the slopes scatter around a value of 2.6. This is similar to the behaviour of the slopes of the simulated galaxies with high central stellar mass surface densities, and could indicate that high shear eventually drives incompressible turbulence