626 research outputs found
HH 114 MMS: a new chemically active outflow
Context. A small group of bipolar protostellar outflows display strong
emission from shock-tracer molecules such as SiO and CH3OH, and are generally
referred to as "chemically active." The best-studied outflow from this group is
the one in L 1157. Aims. We study the molecular emission from the bipolar
outflow powered by the very young stellar object HH 114 MMS and compare its
chemical composition with that of the L1157 outflow. Methods. We have used the
IRAM 30m radio telescope to observe a number of transitions from CO, SiO,
CH3OH, SO, CS, HCN, and HCO+ toward the HH 114 MMS outflow. The observations
consist of maps and a two-position molecular survey. Results. The HH 114 MMS
outflow presents strong emission from a number of shock-tracer molecules that
dominate the appearance of the maps around the central source. The abundance of
these molecules is comparable to the abundance in L 1157. Conclusions. The
outflow from HH 114 MMS is a spectacular new case of a chemically active
outflow.Comment: 4 pages, 3 figures. Accepted for publication in Astronomy &
Astrophysic
Detection of interstellar HCS and its metastable isomer HSC: new pieces in the puzzle of sulfur chemistry
We present the first identification in interstellar space of the thioformyl
radical (HCS) and its metastable isomer HSC. These species were detected toward
the molecular cloud L483 thanks to observations carried out with the IRAM 30m
telescope in the 3 mm band. We derive beam-averaged column densities of 7e12
cm-2 for HCS and 1.8e11 cm-2 for HSC, which translate to fractional abundances
relative to H2 of 2e-10 and 6e-12, respectively. Although the amount of sulfur
locked by these radicals is low, their detection allows to put interesting
constraints on the chemistry of sulfur in dark clouds. Interestingly, the
H2CS/HCS abundance ratio is found to be quite low, around 1, in contrast with
the oxygen analogue case, in which the H2CO/HCO abundance ratio is around 10 in
dark clouds. Moreover, the radical HCS is found to be more abundant than its
oxygen analogue, HCO. The metastable species HOC, the oxygen analogue of HSC,
has not been yet observed in space. These observational constraints are
confronted with the outcome of a recent model of the chemistry of sulfur in
dark clouds. The model underestimates the fractional abundance of HCS by at
least one order of magnitude, overestimates the H2CS/HCS abundance ratio, and
does not provide an abundance prediction for the metastable isomer HSC. These
observations should prompt a revision of the chemistry of sulfur in
interstellar clouds.Comment: Accepted for publication in A&A Letter
Fibers in the NGC1333 proto-cluster
Are the initial conditions for clustered star formation the same as for
non-clustered star formation? To investigate the initial gas properties in
young proto-clusters we carried out a comprehensive and high-sensitivity study
of the internal structure, density, temperature, and kinematics of the dense
gas content of the NGC1333 region in Perseus, one of the nearest and best
studied embedded clusters. The analysis of the gas velocities in the
Position-Position-Velocity space reveals an intricate underlying gas
organization both in space and velocity. We identified a total of 14
velocity-coherent, (tran-)sonic structures within NGC1333, with similar
physical and kinematic properties than those quiescent, star-forming (aka
fertile) fibers previously identified in low-mass star-forming clouds. These
fibers are arranged in a complex spatial network, build-up the observed total
column density, and contain the dense cores and protostars in this cloud. Our
results demonstrate that the presence of fibers is not restricted to low-mass
clouds but can be extended to regions of increasing mass and complexity. We
propose that the observational dichotomy between clustered and non-clustered
star-forming regions might be naturally explained by the distinct spatial
density of fertile fibers in these environments.Comment: 25 pages, 17 figures; Accepted for publication in A&
Chemical modeling of the L1498 and L1517B prestellar cores: CO and HCO+ depletion
Prestellar cores exhibit a strong chemical differentiation, which is mainly
caused by the freeze-out of molecules onto the grain surfaces. Understanding
this chemical structure is important, because molecular lines are often used as
probes to constrain the core physical properties. Here we present new
observations and analysis of the C18O (1-0) and H13CO+ (1-0) line emission in
the L1498 and L1517B prestellar cores, located in the Taurus-Auriga molecular
complex. We model these observations with a detailed chemistry network coupled
to a radiative transfer code. Our model successfully reproduces the observed
C18O (1-0) emission for a chemical age of a few 10^5 years. On the other hand,
the observed H13CO+ (1-0) is reproduced only if cosmic-ray desorption by
secondary photons is included, and if the grains have grown to a bigger size
than average ISM grains in the core interior. This grain growth is consistent
with the infrared scattered light ("coreshine") detected in these two objects,
and is found to increase the CO abundance in the core interior by about a
factor four. According to our model, CO is depleted by about 2-3 orders of
magnitude in the core center.Comment: Accepted for publication in A&
Gravitational collapse of the OMC-1 region
We have investigated the global dynamical state of the Integral Shaped
Filament in the Orion A cloud using new NH (1-0) large-scale, IRAM30m
observations. Our analysis of its internal gas dynamics reveals the presence of
accelerated motions towards the Orion Nebula Cluster, showing a characteristic
blue-shifted profile centred at the position of the OMC-1 South region. The
properties of these observed gas motions (profile, extension, and magnitude)
are consistent with the expected accelerations for the gravitational collapse
of the OMC-1 region and explain both the physical and kinematic structure of
this cloud.Comment: 5 pages, 2 figures; Accepted by A&
Star formation in the vicinity of the IC 348 cluster
Aims. We present molecular line observations of the southwestern part of the
IC 348 young cluster, and we use them together with NIR and mm continuum data
to determine the distribution of dense gas, search for molecular outflows, and
analyze the ongoing star formation activity in the region. Methods. Our
molecular line data consists of C18O(1--0) and N2H+(1--0) maps obtained with
the FCRAO telescope at a resolution of about 50'' and CO(2--1) data obtained
with the IRAM 30m telescope at a resolution of 11''. Results. The dense gas
southwest of IC 348 is concentrated in two groups of dense cores, each of them
with a few solar masses of material and indications of CO depletion at high
density. One of the core groups is actively forming stars, while the other
seems starless. There is evidence for at least three bipolar molecular outflows
in the region, two of them powered by previously identified Class 0 sources,
while the other one is powered by a still not well characterized low-luminosity
object. The ongoing star formation activity is producing a small stellar
subgroup in the cluster. Using the observed core characteristics and the star
formation rate in the cluster we propose that that similar episodes of stellar
birth may have produced the subclustering observed in the halo of IC 348.Comment: 10 pages, 6 figures, A&A accepte
Chains of dense cores in the Taurus L1495/B213 complex
(Abridged) We study the kinematics of the dense gas in the Taurus L1495/B213
filamentary region to investigate the mechanism of core formation. We use
observations of N2H+(1-0) and C18O(2-1) carried out with the IRAM 30m
telescope. We find that the dense cores in L1495/B213 are significantly
clustered in linear chain-like groups about 0.5pc long. The internal motions in
these chains are mostly subsonic and the velocity is continuous, indicating
that turbulence dissipation in the cloud has occurred at the scale of the
chains and not at the smaller scale of the individual cores. The chains also
present an approximately constant abundance of N2H+ and radial intensity
profiles that can be modeled with a density law that follows a softened power
law. A simple analysis of the spacing between the cores using an isothermal
cylinder model indicates that the cores have likely formed by gravitational
fragmentation of velocity-coherent filaments. Combining our analysis of the
cores with our previous study of the large-scale C18O emission from the cloud,
we propose a two-step scenario of core formation in L1495/B213. In this
scenario, named "fray and fragment," L1495/B213 originated from the supersonic
collision of two flows. The collision produced a network of intertwined
subsonic filaments or fibers ("fray" step). Some of these fibers accumulated
enough mass to become gravitationally unstable and fragment into chains of
closely-spaced cores. This scenario may also apply to other regions of star
formation.Comment: 17 pages, 12 figures. Accepted for publication in Astronomy &
Astrophysic
Observations of pre-stellar cores
Our understanding of the physical and chemical structure of pre-stellar
cores, the simplest star-forming sites, has significantly improved since the
last IAU Symposium on Astrochemistry (South Korea, 1999). Research done over
these years has revealed that major molecular species like CO and CS
systematically deplete onto dust grains at the interior of pre-stellar cores,
while species like N2H+ and NH3 survive in the gas phase and can usually be
detected towards the core centers. Such a selective behaviour of molecular
species gives rise to a differentiated (onion-like) chemical composition, and
manifests itself in molecular maps as a dichotomy between centrally peaked and
ring-shaped distributions. From the point of view of star-formation studies,
the identification of molecular inhomogeneities in cores helps to resolve past
discrepancies between observations made using different tracers, and brings the
possibility of self-consistent modelling of the core internal structure. Here I
present recent work on determining the physical and chemical structure of two
pre-stellar cores, L1498 and L1517B, using observations in a large number of
molecules and Monte Carlo radiative transfer analysis. These two cores are
typical examples of the pre-stellar core population, and their chemical
composition is characterized by the presence of large freeze out holes in most
molecular species. In contrast with these chemically processed objects, a new
population of chemically young cores has started to emerge. The characteristics
of its most extreme representative, L1521E, are briefly reviewed.Comment: 10 pages, 5 figures. To appear in IAU 231 conf. proc.
"Astrochemistry: Recent Successes and Current Challenges," eds. D.C. Lis,
G.A. Blake, and E. Herbs
The Musca cloud: A 6 pc-long velocity-coherent, sonic filament
Filaments play a central role in the molecular clouds' evolution, but their
internal dynamical properties remain poorly characterized. To further explore
the physical state of these structures, we have investigated the kinematic
properties of the Musca cloud. We have sampled the main axis of this
filamentary cloud in CO and CO (2--1) lines using APEX
observations. The different line profiles in Musca shows that this cloud
presents a continuous and quiescent velocity field along its 6.5 pc of
length. With an internal gas kinematics dominated by thermal motions (i.e.,
) and large-scale velocity gradients, these results
reveal Musca as the longest velocity-coherent, sonic-like object identified so
far in the ISM. The transonic properties of Musca present a clear departure
from the predicted supersonic velocity dispersions expected in the Larson's
velocity dispersion-size relationship, and constitute the first observational
evidence of a filament fully decoupled from the turbulent regime over
multi-parsec scales.Comment: 12 pages, 6 figures; Accepted for publication in A&
- …