Gas and dust in the star-forming region<i>ρ</i> Oph A

Liseau, R.; Larsson, Bengt; Lunttila, T.; Olberg, M.; Rydbeck, G.; Bergman, P.; Justtanont, K.; Olofsson, G.; Vries, B. L. de

doi:10.1051/0004-6361/201525641

Cited by 46 publications

(71 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The 12 CO channel maps confirm the conclusion by Olofsson & Nyman (1999) of an E-W oriented high-velocity outflow, but also show additional considerable complexity, Fig. 3.…”

Section: Global Characteristicssupporting

confidence: 84%

“…where B 230 is the blackbody brightness at 230 GHz, with S 230 = 112 mJy, D = 0.7 kpc, the dust opacity κ 230 = 0.5 cm 2 g −1 (Liseau et al 2015), and an adopted dust temperature of 45 K (from the SED in Bakker et al 1996b) gives M d ≈ 0.007 M (with an uncertainty of, at least, a factor of four). This suggests about a solar mass of gas in the central region, assuming a dustto-gas ratio of 200.…”

Section: Mass Energy and Momentum Estimatesmentioning

confidence: 99%

“…Olofsson & Nyman (1999) obtained 12 CO and 13 CO J = 1-0 and 2-1 single-dish map data. They found at least three kinematic components: a low-velocity, an intermediatevelocity, and a high-velocity component of total widths ≈15, ≈100, and ≈300 km s −1 , respectively.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

ALMA view of the circumstellar environment of the post-common-envelope-evolution binary system HD 101584

Olofsson

Vlemmings

Maercker

et al. 2015

A&A

View full text Add to dashboard Cite

Aims. We study the circumstellar evolution of the binary HD 101584, consisting of a post-AGB star and a low-mass companion, which is most likely a post-common-envelope-evolution system. Methods. We used ALMA observations of the 12 CO, 13 CO, and C 18 O J = 2−1 lines and the 1.3 mm continuum to determine the morphology, kinematics, masses, and energetics of the circumstellar environment. Results. The circumstellar medium has a bipolar hour-glass structure, seen almost pole-on, formed by an energetic jet, ≈150 km s −1 . We conjecture that the circumstellar morphology is related to an event that took place ≈500 yr ago, possibly a capture event where the companion spiraled in towards the AGB star. However, the kinetic energy of the accelerated gas exceeds the released orbital energy, and, taking into account the expected energy transfer efficiency of the process, the observed phenomenon does not match current common-envelope scenarios. This suggests that another process must augment, or even dominate, the ejection process. A significant amount of material resides in an unresolved region, presumably in the equatorial plane of the binary system.

show abstract

“…The 12 CO channel maps confirm the conclusion by Olofsson & Nyman (1999) of an E-W oriented high-velocity outflow, but also show additional considerable complexity, Fig. 3.…”

Section: Global Characteristicssupporting

confidence: 84%

Section: Mass Energy and Momentum Estimatesmentioning

confidence: 99%

See 1 more Smart Citation

ALMA view of the circumstellar environment of the post-common-envelope-evolution binary system HD 101584

Olofsson

Vlemmings

Maercker

et al. 2015

A&A

View full text Add to dashboard Cite

show abstract

“…Lada et al 2013). The higher average densities, together with the generally higher molecular cloud temperatures (Pattle et al 2015;Liseau et al 2015), imply larger pressures that may accelerate the formation of denser cores and the rate of star formation (e.g. Kennicutt & Evans 2012) compared to the other nearby molecular cloud complexes.…”

Section: Deuterium Fractionmentioning

confidence: 99%

Deuterium fractionation in the Ophiuchus molecular cloud

Punanova

Caselli

Pon

et al. 2016

A&A

View full text Add to dashboard Cite

Context. In cold (T < 25 K) and dense (n H > 10 4 cm −3 ) interstellar clouds, molecules such as CO are significantly frozen onto dust grain surfaces. Deuterium fractionation is known to be very efficient in these conditions as CO limits the abundance of H + 3 , which is the starting point of deuterium chemistry. In particular, N 2 D + is an excellent tracer of dense and cold gas in star-forming regions. Aims. We measure the deuterium fraction, R D , and the CO depletion factor, f d , towards a number of starless and protostellar cores in the L1688 region of the Ophiuchus molecular cloud complex and search for variations based upon environmental differences across L1688. The kinematic properties of the dense gas traced by the N 2 H + and N 2 D + (1−0) lines are also discussed. Methods. Deuterium fraction has been measured via observations of the J = 1−0 transition of N 2 H + and N 2 D + towards 33 dense cores in different regions of L1688. We estimated the CO depletion factor using C 17 O(1−0) and 850 µm dust continuum emission from the SCUBA survey. We carried out all line observations with the IRAM 30 m antenna.Results. The dense cores show large ( 2−40%) deuterium fractions with significant variations between the sub-regions of L1688. The CO depletion factor also varies from one region to another (between 1 and 7). Two different correlations are found between deuterium fraction and CO depletion factor: cores in regions A, B2, and I show increasing R D with increasing f d , similar to previous studies of deuterium fraction in pre-stellar cores; cores in regions B1, B1B2, C, E, F, and H show a steeper R D − f d correlation with large deuterium fractions occurring in fairly quiescent gas with relatively low CO freeze-out factors. These are probably recently formed, centrally concentrated starless cores, which have not yet started the contraction phase towards protostellar formation. We also find that the deuterium fraction is affected by the amount of turbulence, dust temperature, and distance from heating sources in all regions of L1688, although no clear trend is found. Conclusions. The deuterium fraction and amount of CO freeze-out are sensitive to environmental conditions and their variations across L1688 show that regions of the same molecular cloud experience different dynamical, thermal, and chemical histories with consequences for current star formation efficiency and characteristics of future stellar systems. The large pressures present in L1688 may induce the formation of small dense starless cores, unresolved with our beam, where the R D − f d relation appears to deviate from that expected from chemical models. We predict that high angular resolution observations will reconcile observations with theory.

show abstract

“…The dust properties of the ρ Oph cloud are notoriously unusual (Liseau et al 2015), which calls into question standard scaling relations between A V , A λ , CO emission, dust emission, and gas column density. The ρ Oph dark core harbors the star-forming region L1688, which exhibits radio and X-ray emission (Dzib et al 2013) potentially indicative of locally accelerated CRs.…”

Section: Introductionmentioning

confidence: 99%

Calibrating Column Density Tracers With Gamma-Ray Observations of the Ρ Ophiuchi Molecular Cloud

Abrahams

Teachey

2017

ApJ

View full text Add to dashboard Cite

Diffuse gamma-ray emission from interstellar clouds results largely from cosmic ray (CR) proton collisions with ambient gas, regardless of the gas state, temperature, or dust properties of the cloud. The interstellar medium is predominantly transparent to both CRs and gamma-rays, so GeV emission is a unique probe of the total gas column density. The gamma-ray emissivity of a cloud of known column density is then a measure of the impinging CR population and may be used to map the kpc-scale CR distribution in the Galaxy. To this end, we test a number of commonly used column density tracers to evaluate their effectiveness in modeling the GeV emission from the relatively quiescent, nearby ρ Ophiuchi molecular cloud. We confirm that both H I and an appropriate H 2 tracer are required to reproduce the total gas column densities probed by diffuse gamma-ray emisison. We find that the optical depth at 353 GHz (τ 353 ) from Planck reproduces the gamma-ray data best overall based on the test statistic across the entire region of interest, but near infrared stellar extinction also performs very well, with smaller spatial residuals in the densest parts of the cloud.

show abstract

Gas and dust in the star-forming regionρ Oph A

Cited by 46 publications

References 66 publications

ALMA view of the circumstellar environment of the post-common-envelope-evolution binary system HD 101584

ALMA view of the circumstellar environment of the post-common-envelope-evolution binary system HD 101584

Deuterium fractionation in the Ophiuchus molecular cloud

Calibrating Column Density Tracers With Gamma-Ray Observations of the Ρ Ophiuchi Molecular Cloud

Contact Info

Product

Resources

About