Searching for crystal-ice domains in amorphous ices

Martelli, Fausto; Giovambattista, Nicolás; Torquato, Salvatore; Car, Roberto

doi:10.1103/physrevmaterials.2.075601

Cited by 48 publications

(53 citation statements)

References 51 publications

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“…They described uHDA obtained from PIA of ice I at low temperatures as a derailed state along the polymorphic transition path from crystalline ice I to crystalline ice IV. Similarly, Martelli et al (27) demonstrate in MD simulations that, even though HDA is indeed amorphous (lacking “polydispersed icelike structures”), there exist some small domains structurally reminiscent of ice IV. The bump in the uHDA line is reproducible and implies that near ∼0.5 GPa T x (uHDA) appears to approach T x (eHDA).…”

Section: Resultsmentioning

confidence: 85%

Evidence for high-density liquid water between 0.1 and 0.3 GPa near 150 K

Stern

Seidl-Nigsch

Loerting

2019

Proc. Natl. Acad. Sci. U.S.A.

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Thermal stability against crystallization upon isobaric heating at pressure 0.1 ≤ P ≤ 1.9 GPa is compared for five variants of high- (HDA) and very high-density amorphous ice (VHDA) with different preparation history. At 0.1–0.3 GPa expanded HDA (eHDA) and VHDA reach the same state before crystallization, which we infer to be the contested high-density liquid (HDL). Thus, 0.3 GPa sets the high-pressure limit for the possibility to observe HDL for timescales of minutes, hours, and longer. At P > 0.3 GPa the annealed amorphous ices no longer reach the same state before crystallization. Further examination of the results demonstrates that crystallization times are significantly affected both by the density of the amorphous matrix at the crystallization temperature Tx as well as by nanocrystalline domains remaining in unannealed HDA (uHDA) as a consequence of incomplete pressure-induced amorphization.

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Section: Resultsmentioning

confidence: 85%

Evidence for high-density liquid water between 0.1 and 0.3 GPa near 150 K

Stern

Seidl-Nigsch

Loerting

2019

Proc. Natl. Acad. Sci. U.S.A.

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“…That is, LDA-I derived from uHDA crystalizes into hexagonal ice, whereas LDA-II derived from eHDA crystallizes to stacking disordered ice (or also commonly denoted cubic ice) [49][50][51][52], and they concluded that uHDA contains crystalline hexagonal remnants [55]. Recent MD simulations [56] of both uHDA and eHDA at high pressures showed a 'lack of polydisperse ice-like structures', but a weak indication that uHDA contains a 'nonnegligible number of Ih-like molecules' at elevated pressures of 1.4 GPa, clusters composed of 5-10 molecules [56]. We do not find direct evidence for uHDA containing crystalline hexagonal ice, because e.g.…”

Section: Discussionmentioning

confidence: 99%

X-ray studies of the transformation from high- to low-density amorphous water

Mariedahl

Perakis

Späh

et al. 2019

Phil. Trans. R. Soc. A.

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Here we report about the structural evolution during the conversion from high-density amorphous ices at ambient pressure to the low-density state. Using high-energy X-ray diffraction, we have monitored the transformation by following in reciprocal space the structure factor S OO ( Q ) and derived in real space the pair distribution function g OO ( r ). Heating equilibrated high-density amorphous ice (eHDA) at a fast rate (4 K min –1 ), the transition to the low-density form occurs very rapidly, while domains of both high- and low-density coexist. On the other hand, the transition in the case of unannealed HDA (uHDA) and very-high-density amorphous ice is more complex and of continuous nature. The direct comparison of eHDA and uHDA indicates that the molecular structure of uHDA contains a larger amount of tetrahedral motives. The different crystallization behaviour of the derived low-density amorphous states is interpreted as emanating from increased tetrahedral coordination present in uHDA. This article is part of the theme issue ‘The physics and chemistry of ice: scaffolding across scales, from the viability of life to the formation of planets'.

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“…Also, here the (missing) doping-induced enhancement of the H-atom dynamics clearly differs from the findings for crystalline ices, such as ice I, ice V, and ice XII. Let us also draw attention to recent classical molecular dynamics simulations, which demonstrate that polydispersed ice domains are lacking in both LDA and eHDA [58].…”

Section: Discussionmentioning

confidence: 99%

Nature of Water’s Second Glass Transition Elucidated by Doping and Isotope Substitution Experiments

et al. 2019

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Based on calorimetry and dielectric spectroscopy, the influence of dopants as well as H/D-isotope substitution on the dynamics and thermodynamics of expanded high-density amorphous ice (eHDA) is studied. We find that dopants do not significantly alter the phase behavior, the dielectric relaxation times, and the calorimetric glass transition of eHDA. These observations starkly contrast those made for crystalline ices such as ice I h , ice V, ice VI, and ice XII, where suitable dopants enhance the dielectric dynamics by several orders of magnitude and can trigger hydrogen order-disorder transitions, then taking place below the orientational glass transition temperature of undoped samples. This conspicuous contrast to the behavior of crystalline ices strongly argues against point-defect dynamics in amorphous ices and against a previously suggested "crystallinelike" nature of the amorphous ices. Furthermore, H/D substitution also does not affect the calorimetric glass transition in eHDA much, whereas for crystalline ices, the heat capacity increase at the glass transition is roughly halved. In addition, the H/D-isotope shift of the glass transition onset is much larger for crystalline ices than it is for amorphous ices. This observation favors the notion of eHDA's glass transition as a glass-to-liquid transition and is evidence against a mere molecular-reorientation unfreezing at water's second glass transition. Comparing the isotope effect on activation energies for dielectric relaxation with ice V suggests that in amorphous ice water molecules move translationally above T g. Thus, the present work strongly supports that above this glass transition, water does indeed exist in its contested high-density liquid state.

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Searching for crystal-ice domains in amorphous ices

Cited by 48 publications

References 51 publications

Evidence for high-density liquid water between 0.1 and 0.3 GPa near 150 K

Evidence for high-density liquid water between 0.1 and 0.3 GPa near 150 K

X-ray studies of the transformation from high- to low-density amorphous water

Nature of Water’s Second Glass Transition Elucidated by Doping and Isotope Substitution Experiments

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