451 research outputs found
Tentative detection of phosphine in IRC+10216
The J,K = 1,0-0,0 rotational transition of phosphine (PH3) at 267 GHz has
been tentatively identified with a T_MB = 40 mK spectral line observed with the
IRAM 30-m telescope in the C-star envelope IRC+10216. A radiative transfer
model has been used to fit the observed line profile. The derived PH3 abundance
relative to H2 is 6 x 10^(-9), although it may have a large uncertainty due to
the lack of knowledge about the spatial distribution of this species. If our
identification is correct, it implies that PH3 has a similar abundance to that
reported for HCP in this source, and that these two molecules (HCP and PH3)
together take up about 5 % of phosphorus in IRC+10216. The abundance of PH3, as
that of other hydrides in this source, is not well explained by conventional
gas phase LTE and non-LTE chemical models, and may imply formation on grain
surfaces.Comment: 4 pages, 2 figures; accepted for publication in A&A Letter
Study of CS, SiO, and SiS abundances in carbon star envelopes: Assessing their role as gas-phase precursors of dust
Aim: We aim to determine the abundances of CS, SiO, and SiS in a large sample
of carbon star envelopes covering a wide range of mass loss rates to
investigate the potential role that these molecules could play in the formation
of dust in the surroundings of the central AGB star. Methods: We surveyed a
sample of 25 carbon-rich AGB stars in the 2 mm band, using the IRAM
30 m telescope. We performed excitation and radiative transfer calculations
based on the LVG method to model the observed lines of the molecules and to
derive their fractional abundances in the observed CSEs. Results: We detected
CS in all 25 CSEs, SiO in 24 of them, and SiS in 17 sources. We found that CS
and SiS have similar abundances in carbon star envelopes, while SiO is present
with a lower abundance. We also found a strong correlation in which the denser
the envelope, the less abundant are CS and SiO. The trend is however only
tentatively seen for SiS in the range of high mass loss rates. Furthermore, we
found a relation in which the integrated flux of the MgS dust feature at 30 um
increases as the fractional abundance of CS decreases. Conclusions: The decline
in the fractional abundance of CS with increasing density could be due to
gas-phase chemistry in the inner envelope or to adsorption onto dust grains.
The latter possibility is favored by a correlation between the CS fractional
abundance and the 30 um feature, which suggests that CS is efficiently
incorporated onto MgS dust around C-rich AGB stars. In the case of SiO, the
observed abundance depletion with increasing density is most likely caused by
an efficient incorporation onto dust grains. We conclude that CS, SiO (very
likely), and SiS (tentatively) are good candidates to act as gas-phase
precursors of dust in C-rich AGB envelopes.Comment: Accepted for publication in A&A, 19 pages, 11 figures, adbridged
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The chemistry of vibrationally excited H2 in the interstellar medium
The internal energy available in vibrationally excited H2 molecules can be
used to overcome or diminish the activation barrier of various chemical
reactions of interest for molecular astrophysics. In this article we
investigate in detail the impact on the chemical composition of interstellar
clouds of the reactions of vibrationally excited H2 with C+, He+, O, OH, and
CN, based on the available chemical kinetics data. It is found that the
reaction of H2 (v>0) and C+ has a profound impact on the abundances of some
molecules, especially CH+, which is a direct product and is readily formed in
astronomical regions with fractional abundances of vibrationally excited H2,
relative to ground state H2, in excess of 10^(-6), independently of whether the
gas is hot or not. The effects of these reactions on the chemical composition
of the diffuse clouds zeta Oph and HD 34078, the dense PDR Orion Bar, the
planetary nebula NGC 7027, and the circumstellar disk around the B9 star HD
176386 are investigated through PDR models. We find that formation of CH+ is
especially favored in dense and highly FUV illuminated regions such as the
Orion Bar and the planetary nebula NGC 7027, where column densities in excess
of 10^(13) cm^(-2) are predicted. In diffuse clouds, however, this mechanism is
found to be not efficient enough to form CH+ with a column density close to the
values derived from astronomical observations.Comment: accepted for publication in the Astrophysical Journal; 9 pages, 7
figure
Discovery of Interstellar Propylene (CH_2CHCH_3): Missing Links in Interstellar Gas-Phase Chemistry
We report the discovery of propylene (also called propene, CH_2CHCH_3) with
the IRAM 30-m radio telescope toward the dark cloud TMC-1. Propylene is the
most saturated hydrocarbon ever detected in space through radio astronomical
techniques. In spite of its weak dipole moment, 6 doublets (A and E species)
plus another line from the A species have been observed with main beam
temperatures above 20 mK. The derived total column density of propylene is 4
10^13 cm^-2, which corresponds to an abundance relative to H_2 of 4 10^-9,
i.e., comparable to that of other well known and abundant hydrocarbons in this
cloud, such as c-C_3H_2. Although this isomer of C_3H_6 could play an important
role in interstellar chemistry, it has been ignored by previous chemical models
of dark clouds as there seems to be no obvious formation pathway in gas phase.
The discovery of this species in a dark cloud indicates that a thorough
analysis of the completeness of gas phase chemistry has to be done.Comment: 13 pages, 2 figures, accepted for publication in ApJ
The abundance of S- and Si-bearing molecules in O-rich circumstellar envelopes of AGB stars
Aims: We aim to determine the abundances of SiO, CS, SiS, SO, and SO in a
large sample of oxygen-rich AGB envelopes covering a wide range of mass loss
rates to investigate the potential role that these molecules could play in the
formation of dust in these environments.
Methods:We surveyed a sample of 30 oxygen-rich AGB stars in the 2
mm band using the IRAM 30m telescope. We performed excitation and radiative
transfer calculations based on the LVG method to model the observed lines of
the molecules and to derive their fractional abundances in the observed
envelopes.
Results:We detected SiO in all 30 targeted envelopes, as well as CS, SiS, SO,
and SO in 18, 13, 26, and 19 sources, respectively. Remarkably, SiS is not
detected in any envelope with a mass loss rate below M
yr, whereas it is detected in all envelopes with mass loss rates above
that threshold. From a comparison with a previous, similar study on C-rich
sources, it becomes evident that the fractional abundances of CS and SiS show a
marked differentiation between C-rich and O-rich sources, being two orders of
magnitude and one order of magnitude more abundant in C-rich sources,
respectively, while the fractional abundance of SiO turns out to be insensitive
to the C/O ratio. The abundance of SiO in O-rich envelopes behaves similarly to
C-rich sources, that is, the denser the envelope the lower its abundance. A
similar trend, albeit less clear than for SiO, is observed for SO in O-rich
sources.
Conclusions: The marked dependence of CS and SiS abundances on the C/O ratio
indicates that these two molecules form more efficiently in C- than O-rich
envelopes. The decline in the abundance of SiO with increasing envelope density
and the tentative one for SO indicate that SiO and possibly SO act as gas-phase
precursors of dust in circumstellar envelopes around O-rich AGB stars.Comment: 22 pages, 3 figures, Accepted for publications in Astronomy &
Astrophysic
Clues to NaCN formation
ALMA is providing us essential information on where certain molecules form.
Observing where these molecules emission arises from, the physical conditions
of the gas, and how this relates with the presence of other species allows us
to understand the formation of many species, and to significantly improve our
knowledge of the chemistry that occurs in the space. We studied the molecular
distribution of NaCN around IRC +10216, a molecule detected previously, but
whose origin is not clear. High angular resolution maps allow us to model the
abundance distribution of this molecule and check suggested formation paths. We
modeled the emission of NaCN assuming local thermal equilibrium (LTE)
conditions. These profiles were fitted to azimuthal averaged intensity profiles
to obtain an abundance distribution of NaCN. We found that the presence of NaCN
seems compatible with the presence of CN, probably as a result of the
photodissociation of HCN, in the inner layers of the ejecta of IRC +10216.
However, similar as for CH 3 CN, current photochemical models fail to reproduce
this CN reservoir. We also found that the abundance peak of NaCN appears at a
radius of 3 x 10 15 cm, approximately where the abundance of NaCl, suggested to
be the parent species, starts to decay. However, the abundance ratio shows that
the NaCl abundance is lower than that obtained for NaCN. We expect that the LTE
assumption might result in NaCN abundances higher than the real ones. Updated
photochemical models, collisional rates, and reaction rates are essential to
determine the possible paths of the NaCN formation.Comment: 7 pages, 10 figures. Accepted for publication in A&A letter
The Abundance of SiC2 in Carbon Star Envelopes: Evidence that SiC2 is a gas-phase precursor of SiC dust
Silicon carbide dust is ubiquitous in circumstellar envelopes around C-rich
AGB stars. However, the main gas-phase precursors leading to the formation of
SiC dust have not yet been identified. The most obvious candidates among the
molecules containing an Si--C bond detected in C-rich AGB stars are SiC2, SiC,
and Si2C. We aim to study how widespread and abundant SiC2, SiC, and Si2C are
in envelopes around C-rich AGB stars and whether or not these species play an
active role as gas-phase precursors of silicon carbide dust in the ejecta of
carbon stars. We carried out sensitive observations with the IRAM 30m telescope
of a sample of 25 C-rich AGB stars to search for emission lines of SiC2, SiC,
and Si2C in the 2 mm band. We performed non-LTE excitation and radiative
transfer calculations based on the LVG method to model the observed lines of
SiC2 and to derive SiC2 fractional abundances in the observed envelopes. We
detect SiC2 in most of the sources, SiC in about half of them, and do not
detect Si2C in any source, at the exception of IRC +10216. Most of these
detections are reported for the first time in this work. We find a positive
correlation between the SiC and SiC2 line emission, which suggests that both
species are chemically linked, the SiC radical probably being the
photodissociation product of SiC2 in the external layer of the envelope. We
find a clear trend in which the denser the envelope, the less abundant SiC2 is.
The observed trend is interpreted as an evidence of efficient incorporation of
SiC2 onto dust grains, a process which is favored at high densities owing to
the higher rate at which collisions between particles take place. The observed
behavior of a decline in the SiC2 abundance with increasing density strongly
suggests that SiC2 is an important gas-phase precursor of SiC dust in envelopes
around carbon stars.Comment: Published in A&A. 16 pages and 10 figure
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