Discrete stages in the solvation and ionization of hydrogen chloride adsorbed on ice particles

Devlin, J. Paul; Uras, Nevin; Sadlej, Joanna; Buch, V.

doi:10.1038/417269a

Cited by 181 publications

(305 citation statements)

References 26 publications

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“…This finding may explain the variation in and high vapour pressure of, ice samples [19]. Moreover, the vacancies will have a spectrum of trapping energies such that the reaction energy landscape of, for example, a trace gas molecule in the vicinity of one trap could be markedly different from another, similar to what has been observed for ice nanoparticles [20]. More generally, the crystalline ice surface can be expected to be more reactive than previously thought, due to the abundance of vacancy traps and the varied polarity of surface sites.…”

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confidence: 48%

Large variation of vacancy formation energies in the surface of crystalline ice

et al. 2011

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Resolving the atomic structure of the surface of ice particles within clouds, over the temperature range encountered in the atmosphere and relevant to understanding heterogeneous catalysis on ice, remains an experimental challenge. By using first-principles calculations, we show that the surface of crystalline ice exhibits a remarkable variance in vacancy formation energies, akin to an amorphous material. We find vacancy formation energies as low as similar to 0.1-0.2 eV, which leads to a higher than expected vacancy concentration. Because a vacancy's reactivity correlates with its formation energy, ice particles may be more reactive than previously thought. We also show that vacancies significantly reduce the formation energy of neighbouring vacancies, thus facilitating pitting and contributing to pre-melting and quasi-liquid layer formation. These surface properties arise from proton disorder and the relaxation of geometric constraints, which suggests that other frustrated materials may possess unusual surface characteristics. 2 Despite ice being a ubiquitous and well-studied substance, it is surprising that some basic questions about its properties and structure are still debated. For example, Faraday contentiously proposed that the surface of hexagonal ice (Ih) was liquid-like to explain a

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confidence: 48%

Large variation of vacancy formation energies in the surface of crystalline ice

et al. 2011

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“…Since hydronium ions are generated by HCl ionization at 140 K in the present study, these ions are efficiently solvated by water molecules, which are quite mobile at this relatively high temperature. [17,20] On the other hand, amine molecules deposited on the surface after cooling it to 60 K will be surrounded by a smaller number of water molecules, for both neutral and protonated forms. Thus, the most probable situation is n = m. For simplicity, Table 1 shows thermodynamic functions calculated for n = 5 and m = 0-3.…”

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confidence: 99%

Acid–Base Chemistry at the Ice Surface: Reverse Correlation Between Intrinsic Basicity and Proton‐Transfer Efficiency to Ammonia and Methyl Amines

et al. 2007

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Proton transfer from the hydronium ion to NH(3), CH3NH2, and (CH3)2NH is examined at the surface of ice films at 60 K. The reactants and products are quantitatively monitored by the techniques of Cs+ reactive-ion scattering and low-energy sputtering. The proton-transfer reactions at the ice surface proceed only to a limited extent. The proton-transfer efficiency exhibits the order NH3>(CH3)NH2=(CH3)2NH, which opposes the basicity order of the amines in the gas phase or aqueous solution. Thermochemical analysis suggests that the energetics of the proton-transfer reaction is greatly altered at the ice surface from that in liquid water due to limited hydration. Water molecules constrained at the ice surface amplify the methyl substitution effect on the hydration efficiency of the amines and reverse the order of their proton-accepting abilities.

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“…[15] The temperature of the Ru substrate was varied between 40 and 1500 K by a liquid He cryostat and resistive heating. À6 Torr s] at 140 K. Finally, an H 2 O overlayer was deposited to a thickness of 4-12 BLs at temperatures below 100 K. The HCl gas provides excess protons to the film by spontaneous ionization at 140 K, [16,17] and the underlying D 2 O layer serves as a spacer to remove any effects of the Ru substrate on the upper layer, since D 2 O forms a well-ordered film on Ru(0001) at 140 K without dissociation. [18] It was essential to deposit the upper H 2 O layer at low temperature; otherwise the protons remained afloat on the surface during the deposition instead of being buried within the sandwiched layer, as explained below.…”

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confidence: 99%