Intramolecular water-splitting reaction in single collisions of water ions with surfaces

Yao, Yunxi; Giapis, Konstantinos P.

doi:10.1039/c6sc05065d

Cited by 5 publications

(8 citation statements)

References 27 publications

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“…To date, the vast majority of electron/ion irradiation experiments on interstellar ice analogues focus on the chemistry induced upon exposure to ionizing bombardment; [131][132][133][134][135][136] fewer look at the desorbing species. [137][138][139][140] It is even rarer to see both processes compared, as in the work of Abdulgalil et al 141 This study reports that ion/electron induced chemistry is dominant in those environments where the ices are relatively thick (hundreds of layers thick), while EPD is significant when ices are thinner, which is the case as diffuse clouds transition to being dense clouds when reactive accretion has not yet reached a steady state. Consistency with what is known of the radiolysis of liquids and vapours 145,146 would suggest that H/H 2 production is likely to be an important process in photolysis and radiolysis of both simple (e.g.…”

Section: Non-thermal Desorption Through Photon-absorptionmentioning

confidence: 93%

Surface Science Investigations of Icy Mantle Growth on Interstellar Dust Grains in Cooling Environments

Marchione

Rosu-Finsen

Taj

et al. 2019

ACS Earth Space Chem.

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Experimental measurements on the thermal and non-thermal behaviour of water and other simple molecules, including organic compounds such as methanol and benzene, on model interstellar dust grain surfaces and on solid water surfaces using surface science 1 Page 1 of 61 ACS Paragon Plus Environment ACS Earth and Space Chemistry techniques and methodologies are reviewed. A simple qualitative model of the early stages mantle growth arising from a synthesis of the results of such investigations from our own laboratory and others is presented.

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Section: Non-thermal Desorption Through Photon-absorptionmentioning

confidence: 93%

Surface Science Investigations of Icy Mantle Growth on Interstellar Dust Grains in Cooling Environments

Marchione

Rosu-Finsen

Taj

et al. 2019

ACS Earth Space Chem.

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“…However, neither H 2 O + nor D 2 O + ions, scattering on clean Pt, produce any discernible O 2 − signal. This is likely due to molecular hydrogen, present in the ultrahigh vacuum background or formed in situ by an intramolecular water-splitting reaction 18 , which scavenges O atoms from the Pt surface. The O-atom surface coverage must therefore be increased to overcome this problem, which is achieved readily by dosing the surface in situ with O 2 gas.…”

Section: Resultsmentioning

confidence: 99%

“…The formation of fast 16 O 16 O − may appear curious at first, as it requires the presence of 16 O on the surface. But it is readily accounted for by CID of H 2 16 O + ions 18 , which introduce 16 O or 16 OH to the Pt surface. As discussed above, H 2 16 O + bombardment produces no 16 O 16 O − signal unless the Pt surface is dosed with molecular oxygen.…”

Section: Resultsmentioning

confidence: 99%

“…Minerals found on the comet, such as olivine and pyroxene silicates 15 16 and Fe/Ni oxides 17 , are oxidized offering another potential source of oxygen. Thus, collisions of energetic water ions with oxidized minerals on the nucleus surface are probable, with several possible outcomes: (1) collision-induced dissociation (CID) of H 2 O + produces atomic O, atomic H and OH radicals and ions; (2) physical sputtering ejects mineral constituents, including metal and oxygen atoms; and (3) collisional excitation of H 2 O + drives an intramolecular water-splitting reaction 18 , producing molecular H 2 directly. But there is also a surprising forth outcome.…”

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confidence: 99%

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Dynamic molecular oxygen production in cometary comae

Yao

Giapis

2017

Nat Commun

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Abundant molecular oxygen was discovered in the coma of comet 67P/Churyumov–Gerasimenko. Its origin was ascribed to primordial gaseous O2 incorporated into the nucleus during the comet's formation. This thesis was put forward after discounting several O2 production mechanisms in comets, including photolysis and radiolysis of water, solar wind–surface interactions and gas-phase collisions. Here we report an original Eley–Rideal reaction mechanism, which permits direct O2 formation in single collisions of energetic water ions with oxidized cometary surface analogues. The reaction proceeds by H2O+ abstracting a surface O-atom, then forming an excited precursor state, which dissociates to produce O2−. Subsequent photo-detachment leads to molecular O2, whose presence in the coma may thus be linked directly to water molecules and their interaction with the solar wind. This abiotic O2 production mechanism is consistent with reported trends in the 67P coma and raises awareness of the role of energetic negative ions in comets.

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“…It may therefore be possible that some surface‐mediated process, such as dissociative attachment to adsorbed O 2 or CO 2 as suggested by Teolis and Waite (2016), is implicated in the formation of the observed negative ions. Eley‐Rideal reactions between incident ions and surface material (Yao & Giapis, 2017a, 2017b) represent another possible negative ion formation pathway that may be relevant to icy moons and that deserves further study. However, we note that the scale height of the Dione exosphere is expected to be quite small, on the order of ~100 km (Sittler et al, 2004), and we cannot, given the accuracy of the CAPS observations, distinguish between negative pickup ions originating from the surface itself and those from the exosphere near the surface.…”

Section: Discussionmentioning

confidence: 99%

Detection of Negative Pickup Ions at Saturn's Moon Dione

Nordheim

Wellbrock

Jones

et al. 2020

Geophysical Research Letters

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We investigate a possible negative ion feature observed by the Cassini Plasma Spectrometer (CAPS) during a flyby of Saturn's moon Dione that occurred on 7 April 2010. By examining possible particle trajectories, we find that the observed particles are consistent with negative pickup ions originating near the moon's surface. We find that the mass of the negative pickup ions is in the range of 15-25 u and tentatively identify this species as O − , likely resulting from ionization and subsequent pickup from Dione's O 2 -CO 2 exosphere. Our estimates show that the negative ion density is~3 × 10 −3 cm −3 . This is comparable to, but slightly smaller than, that previously reported for the density of O 2 + pickup ions for the same flyby, indicating that negative pickup ions may represent a major loss channel for Dione's exosphere.

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Intramolecular water-splitting reaction in single collisions of water ions with surfaces

Abstract: Direct water splitting into molecular hydrogen and atomic oxygen is demonstrated through single collisions of water ions with generic surfaces at hyperthermal energies.

Cited by 5 publications

References 27 publications

Surface Science Investigations of Icy Mantle Growth on Interstellar Dust Grains in Cooling Environments

Surface Science Investigations of Icy Mantle Growth on Interstellar Dust Grains in Cooling Environments

Dynamic molecular oxygen production in cometary comae

Detection of Negative Pickup Ions at Saturn's Moon Dione

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