A New Determination of the Binding Energy of Atomic Oxygen on Dust Grain Surfaces: Experimental Results and Simulations

He, Jiao; Shi, J.; Hopkins, Tyler; Vidali, Gianfranco; Kaufman, Michael J.

doi:10.1088/0004-637x/801/2/120

Cited by 46 publications

(45 citation statements)

References 28 publications

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“…This is almost twice the value previously considered in chemical models (800 K, Tielens & Allamandola 1987) and was in fact suggested by Hollenbach et al (2009). Model calculations confirm that, in the case of PDRs, higher O atom sticking efficiencies lead to a significant reduction in the gas phase O 2 abundance (He et al 2015). Nevertheless, the low O 2 abundances inferred in CO depletion cores can only be explained by these models if the gas-phase atomic oxygen abundance is significantly lower than 10 −5 .…”

Section: Discussionsupporting

confidence: 71%

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

Wirström

Charnley

Cordiner

et al. 2016

ApJ

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The general lack of molecular oxygen in molecular clouds is an outstanding problem in astrochemistry. Extensive searches with SWAS, Odin and Herschel have only produced two detections; upper limits to the O 2 abundance in the remaining sources observed are about 1000 times lower than predicted by chemical models. Previous atomic oxygen observations and inferences from observations of other molecules indicated that high abundances of O atoms might be present in dense cores exhibiting large amounts of CO depletion. Theoretical arguments concerning the oxygen gas-grain interaction in cold dense cores suggested that, if O atoms could survive in the gas after most of the rest of the heavy molecular material has frozen out on to dust, then O 2 could be formed efficiently in the gas. Using Herschel HIFI we searched a small sample of four depletion cores -L1544, L694-2, L429, Oph D -for emission in the low excitation O 2 N J =3 3 -1 2 line at 487.249 GHz. Molecular oxygen was not detected and we derive upper limits to its abundance in the range N(O 2 )/N(H 2 )≈ (0.6 − 1.6) × 10 −7 . We discuss the absence of O 2 in the light of recent laboratory and observational studies.

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Section: Discussionsupporting

confidence: 71%

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

Wirström

Charnley

Cordiner

et al. 2016

ApJ

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“…Binding energies for radicals can only be obtained in an indirect manner, usually involving the simulation of experimental data, and an exploration of the possible parameter space, using stochastic chemical models. However, there are recent experimental results reporting the experimental determination of the binding energy of atomic oxygen on a range of surfaces (Dulieu et al 2013;He et al 2014He et al , 2015, showing that for some species, direct measurements are possible.…”

Section: Thermal Desorptionmentioning

confidence: 99%

Grain Surface Models and Data for Astrochemistry

et al. 2017

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The cross-disciplinary field of astrochemistry exists to understand the formation, destruction, and survival of molecules in astrophysical environments. Molecules in space are synthesized via a large variety of gas-phase reactions, and reactions on dust-grain surfaces, where the surface acts as a catalyst. A broad consensus has been reached in the astrochemistry community on how to suitably treat gas-phase processes in models, and also on how to present the necessary reaction data in databases; however, no such consensus has yet been reached for grain-surface processes. A team of ∼25 experts covering observational, laboratory and theoretical (astro)chemistry met in summer of 2014 at the Lorentz Center in Leiden with the aim to provide solutions for this problem and to review the current state-of-the-art of grain surface models, both in terms of technical implementation into models as well as the most up-to-date information available from experiments and chemical computations. This review builds on the results of this workshop and gives an outlook for future directions.

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“…, b Collings et al (2003), c Cazaux & Tielens (2004), d ; O 2 (ice) = 1000 K, O 3 (ice) = 1800 K, OH(ice) = 3500 K, e ; H(bare) = 550 K, f Fraser et al (2001), g Garrod & Pauly (2011); H(bare) = 450 K, CO(bare) = 1150 K, h Noble et al (2012a), i Noble et al (2012b), j Dulieu et al (2013); O 3 (bare) = 2100 K, k Karssemeijer et al (2014); Karssemeijer & Cuppen (2014); CO(ice) = 1000-1600 K, l associated with H 2 CO binding energies, m Garrod & Herbst (2006), n Al-Halabi & van Dishoeck (2007), o He et al (2015); O(bare,ice) = (1850 K,1660 K), p Minissale (2014); H 2 CO(bare) = 3400 K, q Karssemeijer, de Wijs & Cuppen (2014); CO 2 (ice) = 2670 K, r Sandford & Allamandola (1990); CO 2 (bare,ice) = (2690 K,2860 K), s Pirronello et al (1997).…”

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confidence: 99%

How chemistry influences cloud structure, star formation, and the IMF

Hocuk¹,

Cazaux

Spaans

et al. 2015

Mon. Not. R. Astron. Soc.

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In the earliest phases of star-forming clouds, stable molecular species, such as CO, are important coolants in the gas phase. Depletion of these molecules on dust surfaces affects the thermal balance of molecular clouds and with that their whole evolution. For the first time, we study the effect of grain surface chemistry (GSC) on star formation and its impact on the initial mass function (IMF). We follow a contracting translucent cloud in which we treat the gas-grain chemical interplay in detail, including the process of freeze-out. We perform 3D hydrodynamical simulations under three different conditions, a pure gas-phase model, a freeze-out model, and a complete chemistry model. The models display different thermal evolution during cloud collapse as also indicated in Hocuk, Cazaux & Spaans 2014, but to a lesser degree because of a different dust temperature treatment, which is more accurate for cloud cores. The equation of state (EOS) of the gas becomes softer with CO freeze-out and the results show that at the onset of star formation, the cloud retains its evolution history such that the number of formed stars differ (by 7%) between the three models. While the stellar mass distribution results in a different IMF when we consider pure freeze-out, with the complete treatment of the GSC, the divergence from a pure gas-phase model is minimal. We find that the impact of freeze-out is balanced by the non-thermal processes; chemical and photodesorption. We also find an average filament width of 0.12 pc (±0.03 pc), and speculate that this may be a result from the changes in the EOS caused by the gas-dust thermal coupling. We conclude that GSC plays a big role in the chemical composition of molecular clouds and that surface processes are needed to accurately interpret observations, however, that GSC does not have a significant impact as far as star formation and the IMF is concerned.

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A New Determination of the Binding Energy of Atomic Oxygen on Dust Grain Surfaces: Experimental Results and Simulations

Cited by 46 publications

References 28 publications

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

Grain Surface Models and Data for Astrochemistry

How chemistry influences cloud structure, star formation, and the IMF

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A New Determination of the Binding Energy of Atomic Oxygen on Dust Grain Surfaces: Experimental Results and Simulations

Cited by 46 publications

References 28 publications

A SEARCH FOR O2 IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

A SEARCH FOR O2 IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

Grain Surface Models and Data for Astrochemistry

How chemistry influences cloud structure, star formation, and the IMF

Contact Info

Product

Resources

About

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL

A SEARCH FOR O₂ IN CO-DEPLETED MOLECULAR CLOUD CORES WITH HERSCHEL