Water in star-forming regions: physics and chemistry from clouds to disks as probed by <i>Herschel</i> spectroscopy

Dishoeck, Ewine van; Kristensen, L. E.; Mottram, J. C.; Benz, A. O.; Bergin, Edwin A.; Caselli, P.; Herpin, Fabrice; Hogerheijde, M. R.; Johnstone, Doug; Liseau, R.; Nisini, B.; Tafalla, M.; Tak, F. F. S. van der; Wyrowski, F.; Baudry, A.; Benedettini, M.; Bjerkeli, P.; Blake, Geoffrey A.; Braine, J.; Bruderer, S.; Cabrit, S.; Cernicharo, J.; Choi, Yunhee; Coutens, A.; Graauw, Th. de; Dominik, C.; Fedele, D.; Fich, M.; Fuente, A.; Furuya, Kenji; Goicoechea, J. R.; Harsono, Daniel; Helmich, Frank; Herczeg, Gregory J.; Jacq, T.; Karska, A.; Kaufman, Michael J.; Keto, Eric; Lamberts, Thanja; Larsson, Bengt; Leurini, S.; Lis, D.; Melnick, Gary J.; Neufeld, David A.; Pagani, L.; Persson, M. V.; Shipman, R.; Taquet, V.; Kempen, T. A. van; Walsh, Catherine; Wampfler, S. F.; Yıldız, U. A.

doi:10.1051/0004-6361/202039084

Cited by 117 publications

(100 citation statements)

References 470 publications

(788 reference statements)

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“…Herschel observations as part of the WISH program also provided detailed constraints on the physics and chemistry toward numerous star-forming regions including protostellar outflows (van Dishoeck et al, 2011). While H 2 O chemistry is not our focus, it is worth highlighting that WISH obtained extensive constraints on the abundances and origin (e.g., ice sputtering vs. gas-phase chemistry) of H 2 O within outflows (van Dishoeck et al, 2021). Additionally, light hydride lines measured through the WISH program provided powerful constraints on the UV and X-ray fields around young protostars and the physics of shock propagation (Benz et al, 2016).…”

Section: Protostellar Outflowsmentioning

confidence: 99%

Astrochemistry With the Orbiting Astronomical Satellite for Investigating Stellar Systems

Bergner

Shirley

Jørgensen

et al. 2022

Front. Astron. Space Sci.

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Chemistry along the star- and planet-formation sequence regulates how prebiotic building blocks—carriers of the elements CHNOPS—are incorporated into nascent planetesimals and planets. Spectral line observations across the electromagnetic spectrum are needed to fully characterize interstellar CHNOPS chemistry, yet to date there are only limited astrochemical constraints at THz frequencies. Here, we highlight advances to the study of CHNOPS astrochemistry that will be possible with the Orbiting Astronomical Satellite for Investigating Stellar Systems (OASIS). OASIS is a NASA mission concept for a space-based observatory that will utilize an inflatable 14-m reflector along with a heterodyne receiver system to observe at THz frequencies with unprecedented sensitivity and angular resolution. As part of a survey of H2O and HD toward ∼100 protostellar and protoplanetary disk systems, OASIS will also obtain statistical constraints on the emission of complex organics from protostellar hot corinos and envelopes as well as light hydrides including NH3 and H2S toward protoplanetary disks. Line surveys of high-mass hot cores, protostellar outflow shocks, and prestellar cores will also leverage the unique capabilities of OASIS to probe high-excitation organics and small hydrides, as is needed to fully understand the chemistry of these objects.

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Section: Protostellar Outflowsmentioning

confidence: 99%

Astrochemistry With the Orbiting Astronomical Satellite for Investigating Stellar Systems

Bergner

Shirley

Jørgensen

et al. 2022

Front. Astron. Space Sci.

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“…On the contrary, at longer wavelength, deep Ionization CH + , 13 CH + , HCO + , H 13 CO + , HC 18 [58]). The emerging scenario is that, in the outer disc, oxygen is depleted onto icy grains, which release oxygen back to the gas-phase in the inner disc as they cross the water snowline, yielding an oxygen-rich inner disc (see also [62]) Overall, the disc molecular inventory is made of a dozen of simple species. Complex molecules (i.e.…”

Section: Chemical Composition and Molecular Inventory Of Protoplanetary Discsmentioning

confidence: 99%

Exploring the link between star and planet formation with Ariel

et al. 2021

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The goal of the Ariel space mission is to observe a large and diversified population of transiting planets around a range of host star types to collect information on their atmospheric composition. The planetary bulk and atmospheric compositions bear the marks of the way the planets formed: Ariel’s observations will therefore provide an unprecedented wealth of data to advance our understanding of planet formation in our Galaxy. A number of environmental and evolutionary factors, however, can affect the final atmospheric composition. Here we provide a concise overview of which factors and effects of the star and planet formation processes can shape the atmospheric compositions that will be observed by Ariel, and highlight how Ariel’s characteristics make this mission optimally suited to address this very complex problem.

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“…T kin is the gas temperature, n H is the molecular hydrogen gas number density, and N spec is the column density of the relevant species under consideration. Owing to the strong UV heating supplied by the OB star population, as well as the high temperatures inferred in the CND from previous observations, we explore temperatures up to 1000 K. We used RADEX owing to its non-LTE molecular excitation capabilities, as well as its widespread use in studies that model interstellar spectra (e.g., Beuther et al 2008;Lique et al 2009;Van Dishoeck et al 2021), including toward the Galactic center (e.g., Wirström et al 2010;Amo-Baladrón et al 2011;Armijos-Abendaño et al 2020). We intend to apply more detailed chemical modeling to these regions in the future in order to further understand their phenomenology.…”

Section: Radiative Transfermentioning

confidence: 99%

Revealing the Physical Conditions around Sgr A* Using Bayesian Inference. I. Observations and Radiative Transfer

James

Viti

Yusef‐Zadeh

et al. 2021

ApJ

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We report subarcsecond Atacama Large Millimeter/submillimeter Array (ALMA) observations between 272 and 375 GHz toward Sgr A * ʼs circumnuclear disk (CND). Our data comprise eight individual pointings, with significant SiO (8 7 -7 6 ) and SO (7-6) emission detected toward 98 positions within these pointings. Additionally, we identify H 2 CS (9 1,9 -8 1,8 ), OCS (25-24), and CH 3 OH (2 1,1 -2 0,2 ) toward a smaller subset of positions. By using the observed peak line flux density, together with a Bayesian inference technique informed by radiative transfer models, we systematically recover the physical gas conditions toward each of these positions. We estimate that the bulk of the surveyed gas has temperature T kin < 500 K and density n H 10 6 cm −3 , consistent with previous studies of similar positions as traced by HCN clumps. However, we identify an uncharacteristically hot (T kin ≈ 600 K) and dense (n H ≈ 10 6 cm −3 ) source in the Northeastern Arm. This position is found to be approximately consistent with a gravitationally bound region dominated by turbulence. We also identify a nearby cold (T kin ≈ 60 K) and extremely dense (n H ≈ 10 7 cm −3 ) position that is again potentially bound and dominated by turbulence. We also determine that the total gas mass contained within the CND is M CND  4 × 10 4 M e . Furthermore, we qualitatively note that the observed chemical enrichment across large scales within the CND is consistent with bulk grain processing, though multiple desorption mechanisms are plausibly responsible. Further chemical modeling is required to identify the physical origin of the grain processing, as well as the localized H 2 CS and OCS emission.

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Water in star-forming regions: physics and chemistry from clouds to disks as probed by Herschel spectroscopy

Cited by 117 publications

References 470 publications

Astrochemistry With the Orbiting Astronomical Satellite for Investigating Stellar Systems

Astrochemistry With the Orbiting Astronomical Satellite for Investigating Stellar Systems

Exploring the link between star and planet formation with Ariel

Revealing the Physical Conditions around Sgr A* Using Bayesian Inference. I. Observations and Radiative Transfer

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