Role of stacking disorder in ice nucleation

Lupi, Laura; Hudait, Arpa; Peters, Baron; Grünwald, Michael; Mullen, Ryan Gotchy; Nguyen, Andrew H.; Molinero, Valeria

doi:10.1038/nature24279

Cited by 220 publications

(274 citation statements)

References 67 publications

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“…Below about 200 K, however, water may be encountered in the metastable cubic form ice I c (e.g., Hobbs, 1974). Recently, studies using diffraction measurements and numerical simulations showed that samples were not composed of pure cubic ice, but rather exhibited crystalline sequences of cubic ice interlaced with sequences of hexagonal ice (e.g., Hudait et al, 2016;Kuhs et al, 2012;Lupi et al, 2017;Malkin et al, 2015;Shallcross and Carpenter, 1957;Thürmer and Nie, 2013). This ice polymorph has been termed stacking disordered ice I sd .…”

Section: Comparison To Literature Datamentioning

confidence: 99%

“…Here, k is the Boltzmann constant, T is the temperature, ν is the molecular volume and σ is the ice-vapor surface tension of the crystalline ice. We assume that the crystalline nano-grains are composed of ice I sd as supported by model studies (Lupi et al, 2017) and X-ray diffraction experiments (Morishige et al, 2009). Since the surface tension of hexagonal and cubic ice are assumed to be very similar, we used the surface tension parameterization of hexagonal ice for ice I sd (σ sd = 0.001 Hale and Plummer, 1974) and assumed an uncertainty of 10 %.…”

Section: The Effect Of Nano-crystalline Ice On the Vapor Pressurementioning

confidence: 99%

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The vapor pressure over nano-crystalline ice

2018

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Abstract. The crystallization of amorphous solid water (ASW) is known to form nano-crystalline ice. The influence of the nanoscale crystallite size on physical properties like the vapor pressure is relevant for processes in which the crystallization of amorphous ices occurs, e.g., in interstellar ices or cold ice cloud formation in planetary atmospheres, but up to now is not well understood. Here, we present laboratory measurements on the saturation vapor pressure over ice crystallized from ASW between 135 and 190 K. Below 160 K, where the crystallization of ASW is known to form nano-crystalline ice, we obtain a saturation vapor pressure that is 100 to 200 % higher compared to stable hexagonal ice. This elevated vapor pressure is in striking contrast to the vapor pressure of stacking disordered ice which is expected to be the prevailing ice polymorph at these temperatures with a vapor pressure at most 18 % higher than that of hexagonal ice. This apparent discrepancy can be reconciled by assuming that nanoscale crystallites form in the crystallization process of ASW. The high curvature of the nano-crystallites results in a vapor pressure increase that can be described by the Kelvin equation. Our measurements are consistent with the assumption that ASW is the first solid form of ice deposited from the vapor phase at temperatures up to 160 K. Nano-crystalline ice with a mean diameter between 7 and 19 nm forms thereafter by crystallization within the ASW matrix. The estimated crystal sizes are in agreement with reported crystal size measurements and remain stable for hours below 160 K. Thus, this ice polymorph may be regarded as an independent phase for many atmospheric processes below 160 K and we parameterize its vapor pressure using a constant Gibbs free energy difference of (982 ± 182) J mol −1 relative to hexagonal ice.

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Section: Comparison To Literature Datamentioning

confidence: 99%

Section: The Effect Of Nano-crystalline Ice On the Vapor Pressurementioning

confidence: 99%

The vapor pressure over nano-crystalline ice

2018

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“…On the basis of quantum mechanical calculations Engel et al (2015) have suggested that the anharmonic vibrational energies favour the hexagonal form as a consequence of differences in the fourth nearest-neighbour protons, related to the occurrence of the topologically different boat and chair forms of the sixmembered water rings in cubic and hexagonal ice. Still, as nucleation (and growth) for supercooled water is kinetically controlled, freezing may well start also with a cubic or a stacking-disordered nucleus (Lupi et al, 2017). The subsequent growth appears experimentally to follow a fast s ¼ 2 Markov chain prescription, before any annealing has time to set in for temperatures below approximately 240 K. It is noteworthy that branching (twinning) has been observed for a significant percentage of snow crystals formed at temperatures higher than about 238 K (Kajikawa et al, 1980), which likely have formed from a cubic (or stacking-faulty) nucleus growing along directions separated by the octahedral angle of 70.53 (i.e.…”

Section: Markov Processes In Relation To the Growth Physics Of Stackimentioning

confidence: 99%

A Markov theoretic description of stacking-disordered aperiodic crystals including ice and opaline silica

2018

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This article reviews the Markov theoretic description of one-dimensional aperiodic crystals, describing the stacking-faulted crystal polytype as a special case of an aperiodic crystal. Under this description the centrosymmetric unit cell underlying a topologically centrosymmetric crystal is generalized to a reversible Markov chain underlying a reversible aperiodic crystal. It is shown that for the close-packed structure almost all stackings are irreversible when the interaction reichweite s > 4. Moreover, the article presents an analytic expression of the scattering cross section of a large class of stacking-disordered aperiodic crystals, lacking translational symmetry of their layers, including ice and opaline silica (opal CT). The observed stackings and their underlying reichweite are then related to the physics of various nucleation and growth processes of disordered ice. The article discusses how the derived expressions of scattering cross sections could significantly improve implementations of Rietveld's refinement scheme and compares this Q-space approach with the pair-distribution function analysis of stacking-disordered materials.

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“…Recently, this attention has been motivated by the significant role played by the surface melting of ice in many natural phenomena such as snow and ice disaster and melting glaciers. As a result, the solid-liquid phase transition of water has been the subject of numerous experimental and theoretical investigations [1][2][3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Surface phase-transition dynamics of ice probed by terahertz time-domain spectroscopy

et al. 2018

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In this paper, we present an investigation of the solid-liquid phase-transition process of ice based on terahertz time-domain spectroscopy (THz-TDS), which can precisely demonstrate the low-frequency vibrational and rotational modes in gaseous or condensed state materials. The intensity of the transmitted signal is used to characterize the interaction between the terahertz wave and the melting ice. The structure transition lead to the change of physical properties such as dielectric constant with the melting of the ice. When the temperature gradually rises, the H 2 O molecules on ice surface overcome the hydrogenbond interaction and start to rotate under the driving of THz field which enhancing the interaction between water molecules and incident terahertz radiation. As H 2 O is a polar molecule, a dipolar moment will be induced, which contributes to the dielectric polarization. An analysis of the intensities and dielectric constant of THz-TDS signal peaks reveals the dynamic and continuous melting process on the surface of ice at room temperature.

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Role of stacking disorder in ice nucleation

Cited by 220 publications

References 67 publications

The vapor pressure over nano-crystalline ice

The vapor pressure over nano-crystalline ice

A Markov theoretic description of stacking-disordered aperiodic crystals including ice and opaline silica

Surface phase-transition dynamics of ice probed by terahertz time-domain spectroscopy

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