Mechanism of anisotropic surface self-diffusivity at the prismatic ice-vapor interface

Ivan Gladich; Amrei Oswald; Natalie Bowens; Sam Naatz; Penny Rowe; Martina Roeselova; Steven Neshyba

doi:10.1039/c5cp01330e

Mechanism of anisotropic surface self-diffusivity at the prismatic ice-vapor interface

Ivan Gladich^*, Amrei Oswald, Natalie Bowens, Sam Naatz, Penny Rowe, Martina Roeselova, Steven Neshyba

^*Corresponding author for this work

QEERI - Energy Center

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Predictive theoretical models for mesoscopic roughening of ice require improved understanding of attachment kinetics occurring at the ice-vapor interface. Here, we use classical molecular dynamics to explore the generality and mechanics of a transition from anisotropic to isotropic self-diffusivity on exposed prismatic surfaces. We find that self-diffusion parallel to the crystallographic a-axis is favored over the c-axis at sub-melt temperatures below about -35 °C, for three different representations of the water-water intermolecular potential. In the low-temperature anisotropic regime, diffusion results from interstitial admolecules encountering entropically distinct barriers to diffusion in the two in-plane directions. At higher temperatures, isotropic self-diffusion occurring deeper within the quasi-liquid layer becomes the dominant mechanism, owing to its larger energy of activation.

Original language	English
Pages (from-to)	22947-22958
Number of pages	12
Journal	Physical Chemistry Chemical Physics
Volume	17
Issue number	35
DOIs	https://doi.org/10.1039/c5cp01330e
Publication status	Published - 7 Aug 2015

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abstract = "Predictive theoretical models for mesoscopic roughening of ice require improved understanding of attachment kinetics occurring at the ice-vapor interface. Here, we use classical molecular dynamics to explore the generality and mechanics of a transition from anisotropic to isotropic self-diffusivity on exposed prismatic surfaces. We find that self-diffusion parallel to the crystallographic a-axis is favored over the c-axis at sub-melt temperatures below about -35 °C, for three different representations of the water-water intermolecular potential. In the low-temperature anisotropic regime, diffusion results from interstitial admolecules encountering entropically distinct barriers to diffusion in the two in-plane directions. At higher temperatures, isotropic self-diffusion occurring deeper within the quasi-liquid layer becomes the dominant mechanism, owing to its larger energy of activation.",

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T1 - Mechanism of anisotropic surface self-diffusivity at the prismatic ice-vapor interface

AU - Gladich, Ivan

AU - Oswald, Amrei

AU - Bowens, Natalie

AU - Naatz, Sam

AU - Rowe, Penny

AU - Roeselova, Martina

AU - Neshyba, Steven

PY - 2015/8/7

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N2 - Predictive theoretical models for mesoscopic roughening of ice require improved understanding of attachment kinetics occurring at the ice-vapor interface. Here, we use classical molecular dynamics to explore the generality and mechanics of a transition from anisotropic to isotropic self-diffusivity on exposed prismatic surfaces. We find that self-diffusion parallel to the crystallographic a-axis is favored over the c-axis at sub-melt temperatures below about -35 °C, for three different representations of the water-water intermolecular potential. In the low-temperature anisotropic regime, diffusion results from interstitial admolecules encountering entropically distinct barriers to diffusion in the two in-plane directions. At higher temperatures, isotropic self-diffusion occurring deeper within the quasi-liquid layer becomes the dominant mechanism, owing to its larger energy of activation.

AB - Predictive theoretical models for mesoscopic roughening of ice require improved understanding of attachment kinetics occurring at the ice-vapor interface. Here, we use classical molecular dynamics to explore the generality and mechanics of a transition from anisotropic to isotropic self-diffusivity on exposed prismatic surfaces. We find that self-diffusion parallel to the crystallographic a-axis is favored over the c-axis at sub-melt temperatures below about -35 °C, for three different representations of the water-water intermolecular potential. In the low-temperature anisotropic regime, diffusion results from interstitial admolecules encountering entropically distinct barriers to diffusion in the two in-plane directions. At higher temperatures, isotropic self-diffusion occurring deeper within the quasi-liquid layer becomes the dominant mechanism, owing to its larger energy of activation.

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DO - 10.1039/c5cp01330e

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Mechanism of anisotropic surface self-diffusivity at the prismatic ice-vapor interface

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