1,852 research outputs found
Mass inflow rate into the Central Molecular Zone: observational determination and evidence of episodic accretion
It is well known that the Galactic bar drives a gas inflow into the Central
Molecular Zone, which fuels star formation, accretion onto the central
super-massive black hole, and large-scale outflows. This inflow happens mostly
through two symmetrical dust-lanes, similar to those often seen in external
barred galaxies. Here we use the fact that the Milky Way dust-lanes have been
previously identified in CO datacubes and a simple geometrical model to
derive the first observational determination of the mass inflow rate into the
Central Molecular Zone. We find that the time-averaged inflow rate along the
near-side dust lane is and along the
far-side dust lane is , which gives a
total inflow of . We also provide the
time series of the inflow rate for the future few Myr. The latter
shows that the inflow rate is variable with time, supporting a scenario of
episodic accretion onto the Central Molecular Zone.Comment: Accepted for publication in MNRA
Which feedback mechanisms dominate in the high-pressure environment of the Central Molecular Zone?
This article has been accepted for publication in Monthly Notices of the Royal Astronomical Society ©: 2020 The Author(s). Published by Oxford University Press on behalf of the Royal Astronomical Society. All rights reserved. Final published version available at https://doi.org/10.1093/mnras/staa2719.Supernovae (SNe) dominate the energy and momentum budget of stellar feedback, but the efficiency with which they couple to the interstellar medium (ISM) depends strongly on how effectively early, pre-SN feedback clears dense gas from star-forming regions. There are observational constraints on the magnitudes and timescales of early stellar feedback in low ISM pressure environments, yet no such constraints exist for more cosmologically typical high ISM pressure environments. In this paper, we determine the mechanisms dominating the expansion of H ii regions as a function of size-scale and evolutionary time within the high-pressure (P/kB ∼ 107 − 8 K cm−3) environment in the inner 100 pc of the Milky Way. We calculate the thermal pressure from the warm ionised (PHII; 104 K) gas, direct radiation pressure (Pdir), and dust processed radiation pressure (PIR). We find that (1) Pdir dominates the expansion on small scales and at early times (0.01-0.1 pc; 0.1 pc; >1 Myr); (3) during the first ≲ 1 Myr of growth, but not thereafter, either PIR or stellar wind pressure likely make a comparable contribution. Despite the high confining pressure of the environment, natal star-forming gas is efficiently cleared to radii of several pc within ∼ 2 Myr, i.e. before the first SNe explode. This ‘pre-processing’ means that subsequent SNe will explode into low density gas, so their energy and momentum will efficiently couple to the ISM. We find the H ii regions expand to a radius of ∼ 3pc, at which point they have internal pressures equal with the surrounding external pressure. A comparison with H ii regions in lower pressure environments shows that the maximum size of all H ii regions is set by pressure equilibrium with the ambient ISM.Peer reviewe
Multicomponent kinematics in a massive filamentary IRDC
To probe the initial conditions for high-mass star and cluster formation, we
investigate the properties of dense filaments within the infrared dark cloud
G035.39-00.33 (IRDC G035.39) in a combined Very Large Array (VLA) and the Green
Bank Telescope (GBT) mosaic tracing the NH3 (1,1) and (2,2) emission down to
0.08 pc scales. Using agglomerative hierarchical clustering on multiple
line-of-sight velocity component fitting results, we identify seven extended
velocity-coherent components in our data, likely representing spatially
coherent physical structures, some exhibiting complex gas motions. The velocity
gradient magnitude distribution peaks at its mode of 0.35 km/s/pc and has a
long tail extending into higher values of 1.5 - 2 km/s/pc, and is generally
consistent with those found toward the same cloud in other molecular tracers
and with the values found towards nearby low-mass dense cloud cores at the same
scales. Contrary to observational and theoretical expectations, we find the
non-thermal ammonia line widths to be systematically narrower (by about 20%)
than those of N2H+ (1-0) line transition observed with similar resolution. If
the observed ordered velocity gradients represent the core envelope solid-body
rotation, we estimate the specific angular momentum to be about 2 x 10^21
cm^2/s, similar to the low-mass star-forming cores. Together with the previous
finding of subsonic motions in G035.39, our results demonstrate high levels of
similarity between kinematics of a high-mass star-forming IRDC and the low-mass
star formation regime.Comment: 22 pages, 14 figures, accepted to Ap
JWST reveals widespread CO ice and gas absorption in the Galactic Center cloud G0.253+0.016
We report JWST NIRCam observations of G0.253+0.016, the molecular cloud in
the Central Molecular Zone known as The Brick, with the F182M, F187N, F212N,
F410M, F405N, and F466N filters. We catalog 56,146 stars detected in all 6
filters using the crowdsource package. Stars within and behind The Brick
exhibit prodigious absorption in the F466N filter that is produced by a
combination of CO ice and gas. In support of this conclusion, and as a general
resource, we present models of CO gas and ice and CO ice in the F466N,
F470N, and F410M filters. Both CO gas and ice may contribute to the observed
stellar colors. We show, however, that CO gas does not absorb the Pf and
Hu lines in F466N, but that these lines show excess absorption,
indicating that CO ice is also present and contributes to observed F466N
absorption. The most strongly absorbed stars in F466N are extincted by 2
magnitudes, corresponding to 80\% flux loss. This high observed absorption
requires very high column densities of CO, requiring total CO column that is in
tension with standard CO abundance and/or gas-to-dust ratios. There is
therefore likely to be a greater CO/H ratio (X) and more
dust per H molecule () in the Galactic Center than the Galactic
disk. Ice and/or gas absorption is observed even in the cloud outskirts,
implying that additional caution is needed when interpreting stellar photometry
in filters that overlap with ice bands throughout our Galactic Center. The
widespread CO absorption in our Galactic Center hints that significant ice
absorption is likely present in other galactic centers.Comment: Submitted to ApJ. Revised after second referee report. 16 pages, 11
figure
Spectral Stacking of Radio-Interferometric Data
Mapping molecular line emission beyond the bright low-J CO transitions is
still challenging in extragalactic studies, even with the latest generation of
(sub-)mm interferometers, such as ALMA and NOEMA. We summarise and test a
spectral stacking method that has been used in the literature to recover
low-intensity molecular line emission, such as HCN(1-0), HCO+(1-0), and even
fainter lines in external galaxies. The goal is to study the capabilities and
limitations of the stacking technique when applied to imaged interferometric
observations. The core idea of spectral stacking is to align spectra of the low
S/N spectral lines to a known velocity field calculated from a higher S/N line
expected to share the kinematics of the fainter line, e.g., CO(1-0) or 21-cm
emission. Then these aligned spectra can be coherently averaged to produce
potentially high S/N spectral stacks. Here, we use imaged simulated
interferometric and total power observations at different signal-to-noise
levels, based on real CO observations. For the combined interferometric and
total power data, we find that the spectral stacking technique is capable of
recovering the integrated intensities even at low S/N levels across most of the
region where the high S/N prior is detected. However, when stacking
interferometer-only data for low S/N emission, the stacks can miss up to 50% of
the emission from the fainter line. A key result of this analysis is that the
spectral stacking method is able to recover the true mean line intensities in
low S/N cubes and to accurately measure the statistical significance of the
recovered lines. To facilitate the application of this technique we provide a
public Python package, called PyStacker.Comment: 10 pages, 10 figures, accepted for pub in A&A, Apr 28, 202
A Census of Early-phase High-mass Star Formation in the Central Molecular Zone
We present new observations of the C-band continuum emission and masers to assess high-mass (>8 ) star formation at early evolutionary phases in the inner 200 pc of the Central Molecular Zone (CMZ) of the Galaxy. The continuum observation is complete to free–free emission from stars above 10–11 in 91% of the covered area. We identify 104 compact sources in the continuum emission, among which five are confirmed ultracompact H ii regions, 12 are candidates of ultracompact H ii regions, and the remaining 87 sources are mostly massive stars in clusters, field stars, evolved stars, pulsars, extragalactic sources, or of unknown nature that is to be investigated. We detect class ii CH3OH masers at 23 positions, among which six are new detections. We confirm six known H2CO masers in two high-mass star-forming regions and detect two new H2CO masers toward the Sgr C cloud, making it the ninth region in the Galaxy that contains masers of this type. In spite of these detections, we find that current high-mass star formation in the inner CMZ is only taking place in seven isolated clouds. The results suggest that star formation at early evolutionary phases in the CMZ is about 10 times less efficient than expected from the dense gas star formation relation, which is in line with previous studies that focus on more evolved phases of star formation. This means that if there will be any impending, next burst of star formation in the CMZ, it has not yet begun
CMZoom IV. Incipient High-Mass Star Formation Throughout the Central Molecular Zone
In this work, we constrain the star-forming properties of all possible sites
of incipient high-mass star formation in the Milky Way's Galactic Center. We
identify dense structures using the CMZoom 1.3mm dust continuum catalog of
objects with typical radii of 0.1pc, and measure their association with
tracers of high-mass star formation. We incorporate compact emission at 8, 21,
24, 25, and 70um from MSX, Spitzer, Herschel, and SOFIA, catalogued young
stellar objects, and water and methanol masers to characterize each source. We
find an incipient star formation rate (SFR) for the CMZ of ~0.08 Msun yr^{-1}
over the next few 10^5 yr. We calculate upper and lower limits on the CMZ's
incipient SFR of ~0.45 Msun yr^{-1} and ~0.05 Msun yr^{-1} respectively,
spanning between roughly equal to and several times greater than other
estimates of CMZ's recent SFR. Despite substantial uncertainties, our results
suggest the incipient SFR in the CMZ may be higher than previously estimated.
We find that the prevalence of star formation tracers does not correlate with
source volume density, but instead ~75% of high-mass star formation is found in
regions above a column density ratio (N_{SMA}/N_{Herschel}) of ~1.5. Finally,
we highlight the detection of ``atoll sources'', a reoccurring morphology of
cold dust encircling evolved infrared sources, possibly representing HII
regions in the process of destroying their envelopes.Comment: Accepted for publication in Ap
Towards an Intelligent Tutor for Mathematical Proofs
Computer-supported learning is an increasingly important form of study since
it allows for independent learning and individualized instruction. In this
paper, we discuss a novel approach to developing an intelligent tutoring system
for teaching textbook-style mathematical proofs. We characterize the
particularities of the domain and discuss common ITS design models. Our
approach is motivated by phenomena found in a corpus of tutorial dialogs that
were collected in a Wizard-of-Oz experiment. We show how an intelligent tutor
for textbook-style mathematical proofs can be built on top of an adapted
assertion-level proof assistant by reusing representations and proof search
strategies originally developed for automated and interactive theorem proving.
The resulting prototype was successfully evaluated on a corpus of tutorial
dialogs and yields good results.Comment: In Proceedings THedu'11, arXiv:1202.453
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