Dielectric Behavior of Cubic and Hexagonal Ices at Low Temperatures

Gough, S. R.; Davidson, D. W.

doi:10.1063/1.1672795

Cited by 103 publications

(63 citation statements)

References 16 publications

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“…Taking into account the simplicity of the model, these values of a are in a reasonable agreement with the jump length 1.5-1.9 Å found in supercooled water by the quasielastic neutron scattering [82] and NMR [83]. The estimated activation energy ~ 46 kJ/mol is comparable to that found by dielectric spectroscopy in different ices, 44-57 kJ/mol [68][69][70][84][85][86][87]. In spite of the very simplistic and schematic character of our estimate, it shows that the rotational tunneling effects can indeed lead to the experimentally measured value of fragility, m = 14, with the values of the model parameters corresponding to that of supercooled water.…”

Section: Qualitative Estimates Of Possible Tunnelingsupporting

confidence: 72%

“…This result justifies our assignment of the α-process to the structural relaxation in amorphous water. In addition, Figure 5a presents the literature data on relaxation rate in cubic ice I c [68,69] and in hexagonal ice I hex [70]. The activation energy for dielectric relaxation in cubic and hexagonal ices in the temperature range of interest is similar and amount to 44 and 47 kJ/mole, respectively.…”

Section: Relaxation Time In Vapor Deposited Watermentioning

confidence: 96%

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Quantum effects in the dynamics of deeply supercooled water

et al. 2015

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Despite its simple chemical structure water remains one of the most puzzling liquids with many anomalies at low temperatures. Combining neutron scattering and dielectric relaxation spectroscopy we show that quantum fluctuations are not negligible in deeply supercooled water.Our dielectric measurements revealed the anomalously weak temperature dependence of structural relaxation in vapor deposited water close to the glass transition temperature T g ~136K.We demonstrate that this anomalous behavior can be explained well by quantum effects. These results have significant implications for our understanding of water dynamics.2

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Section: Qualitative Estimates Of Possible Tunnelingsupporting

confidence: 72%

Section: Relaxation Time In Vapor Deposited Watermentioning

confidence: 96%

Quantum effects in the dynamics of deeply supercooled water

et al. 2015

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“…Our interest in the dielectric properties of water-in-oil emulsions and dispersions of ice microcrystals is twofold: it has been proved that a better understanding of the dynamics of water molecules in ice can be achieved by studying different forms of ice [14,15], including dispersions of ice microcrystals [6][7][8][9]. On the other hand, these relatively simple and easy to manipulate systems may serve as models for more complicated systems, such as food emulsions and tissue.…”

Section: -Introductionmentioning

confidence: 99%

“…In this work we study the characteristics of this relaxation at different stages of its evolution with time. The main feature of our approach to the topic is that we discuss the time-induced changes of the characteristics of the dielectric relaxation of water molecules in ice microcrystals in relation to similar effects observed in different forms of ice, such as pure monocrystals [10,11], polycrystalline pure samples [12], polar ice samples [13] and samples with high concentration of imperfections [14,15], and in relation to mechanisms suggested for ice at the molecular level.…”

Section: -Introductionmentioning

confidence: 99%

Evolution with time of the dielectric properties of dispersed ice microcrystals

1991

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Summary. --The evolution with time of the characteristics of the dielectric relaxation of water molecules in dispersions of ice microcrystals has been studied by means of the thermally stimulated depolarization current (TSDC) method. With advancing stage of evolution, i.e. with increasing preservation time at constant preservation temperature and with increasing preservation temperature at constant preservation time, the mean values of relaxation time and activation energy have been found to decrease. The extent and the rate of the evolution have been compared to those in other forms of ice: ice samples with high content of disturbance, polycrystalline ice samples and single ice crystals. The observed similarities and differences in the behaviour of the different ice forms have been discussed in terms of the influence of extrinsic physical and chemical defects on the generation and motion of orientational Bjerrum defects.PACS 77.30 -Polarization and depolarization effects. PACS 82.70 -Disperse systems.

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“…This may arise from the fact that pressurization of ice induces rejection of ionic impurities from the specimen. 28) Even under such conditions, a residual portion escaped from the segregation acted to enhance the orientational mobility of the water molecules. The rate of spontaneous temperature change was analyzed to derive the enthalpy relaxation time governing the freezing process.…”

Section: P/gpamentioning

confidence: 99%

Ultra-slow relaxation in ice and related substances

Suga

2005

Proceedings of the Japan Academy. Ser. B: Physical and Biologic

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Introduction.A wide range of substances can be vitrified by cooling their liquids. At temperatures well below the fusion point, the relaxation time for viscous flow becomes so long that the liquid ultimately behaves like a solid. The glassy states of liquid are found to exhibit the glass transition T g and residual entropy S 0 as indicative of non-ergodicity of the frozen-in non-equilibrium system.1) The liquid undergoes a heat capacity discontinuity over a narrow temperature interval of T g , where the relaxation time for the structural change in a liquid becomes of the order of 1 ks that corresponds to the time scale for a single heat-capacity determination.Corresponding to the C p drop, the entropy of the liquid bends at T g and results in residual entropy S 0 that is a measure of the extent of frozen-in disorder. These quantities are highly time-dependent. If the liquid were cooled with an infinitely slow rate, the liquid follows the extrapolated curve of entropy of the undercooled liquid and finally intersects that of the corresponding crystal. Since any disordered system with less entropy than that of the crystal cannot be considered, the entropy of the equilibrium liquid must bend at this temperature in order to avoid the entropy crisis. The temperature is known as the Kauzmann temperature T K . Thus the seemingly second-order character of the glass transitions in real liquids is believed to be a kinetic manifestation of the underlying second-order phase transition in the "equilibrium" liquid. Essentially the same phenomena were found to occur also in some crystalline solids that have orienta- Abstract: Of prime interest in numerous studies on water, an important substance to all living systems, may be its physical, chemical, biological characteristics in our internal and external environments. One of the central problems underlying all these researches is a basic structural problem. An important question was why ordinary ice did not obey the third law of thermodynamics. The proton-disordered phase I h remains down to the lowest temperature without exhibiting any indication of phase transition. We found that the glass transition is not a characteristic property of liquid but of wide occurrence in condensed systems that failed to maintain thermal equilibrium during continuous cooling. Crystalline substance that exhibited freezing-in process on cooling was designated as "glassy crystals". In fact, ice I h exhibited a glass transition at around 110 K due to slowing down of reorientational motion of the water molecules. A particular kind of impurity was found to accelerate dramatically the motion, and to induce a long-awaited phase transition at 72 K. The transition removed a substantial fraction of the residual entropy of ice. The dopant acted as a kind of catalysis for releasing the immobilized non-equilibrium state to recover thermal equilibrium in the laboratory time. Structure and some properties of the ordered low temperature phase, designated as ice XI, are discussed. The same ordering processes observ...

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Dielectric Behavior of Cubic and Hexagonal Ices at Low Temperatures

Cited by 103 publications

References 16 publications

Quantum effects in the dynamics of deeply supercooled water

Quantum effects in the dynamics of deeply supercooled water

Evolution with time of the dielectric properties of dispersed ice microcrystals

Ultra-slow relaxation in ice and related substances

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