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Liquid water in the domain of cubic crystalline ice Ic (1997)

Jenniskens, P. ; Banham, S. F. ; Blake, D. F. ; [et al.]

American Institute of Physics

In: Journal of Chemical Physics. 1997; 107(4): 1232-1241. Published 1997 Jul 22. doi: 10.1063/1.474468.

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Publication Date: 1997-07-22

Print ISSN: 0021-9606

Electronic ISSN: 1089-7690

Topics: Chemistry and Pharmacology , Physics

Published by American Institute of Physics

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Crystallization of Amorphous Water Ice in the Solar System (1996)

Jenniskens, P. ; Blake, D. F.

Institute of Physics

In: Astrophysical Journal. 1996; 473(2): 1104-1113. Published 1996 Dec 20. doi: 10.1086/178220.

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Publication Date: 1996-12-20

Print ISSN: 0004-637X

Electronic ISSN: 1538-4357

Topics: Physics

Published by Institute of Physics

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High-Density Amorphous Ice, the Frost on Interstellar Grains (1995)

Jenniskens, P. ; Blake, D. F. ; Wilson, M. A. ; [et al.]

Institute of Physics

In: Astrophysical Journal. 1995; 455: 389. Published 1995 Jan 01. doi: 10.1086/176585.

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Publication Date: 1995-01-01

Print ISSN: 0004-637X

Electronic ISSN: 1538-4357

Topics: Physics

Published by Institute of Physics

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Crystallization of amorphous water ice in the solar system (1996)

Blake, D. F. ; Jenniskens, P.

In: Other Sources

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Publication Date: 2011-08-24

Description: Electron diffraction studies of vapor-deposited water ice have characterized the dynamical structural changes during crystallization that affect volatile retention in cometary materials. Crystallization is found to occur by nucleation of small domains, while leaving a significant part of the amorphous material in a slightly more relaxed amorphous state that coexists metastably with cubic crystalline ice. The onset of the amorphous relaxation is prior to crystallization and coincides with the glass transition. Above the glass transition temperature, the crystallization kinetics are consistent with the amorphous solid becoming a "strong" viscous liquid. The amorphous component can effectively retain volatiles during crystallization if the volatile concentration is approximately 10% or less. For higher initial impurity concentrations, a significant amount of impurities is released during crystallization, probably because the impurities are trapped on the surfaces of micropores. A model for crystallization over long timescales is described that can be applied to a wide range of impure water ices under typical astrophysical conditions if the fragility factor D, which describes the viscosity behavior, can be estimated.

Keywords: Lunar and Planetary Science and Exploration

Type: The Astrophysical journal (ISSN 0004-637X); Volume 473; 2 Pt 1; 1104-13

Format: text

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The Structural Properties of Vapor Deposited Water Ice and Astrophysical Implications (1996)

Blake, D. F. ; Jenniskens, P. ; Chang, Sherwood

In: Other Sources

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Publication Date: 2019-07-18

Description: Films of vapor deposited water ice at low temperature (T〈30 K) show a number of interesting structural changes during a gradual warmup. We would like to talk about the structure of the low temperature high density amorphous form of water ice, the process of crystallization, and some recent work on the morphological changes of water ice films at high temperature. The studies of the high density amorphous form are from in-situ electron microscopy as well as numerical simulations of molecular dynamics and have lead to new insights into the physical distinction between this high density amorphous form and the low density amorphous form. For the process of crystallization, we propose a model that describes the crystallization of water ice from the amorphous phase to cubic ice in terms of the nucleation of small domains in the ice. This model agrees well with the behavior of water ice in our electron microscopy studies and finds that pure water above the glass transition is a strong liquid. In more recent work, we have concentrated on temperatures above the crystallization temperature and we find interesting morphological changes related to the decrease in viscosity of the amorphous component in the cubic crystalline regime. Given enough time, we would like to put these results in an astrophysical context and discuss some observed features of the frost on interstellar grains and the bulk ice in comets.

Keywords: Astrophysics

Type: 1996 International Symposium on the Physics and Chemistry of Ice; Aug 26, 1996 - Aug 30, 1996; Hanover, NH; United States

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Liquid water in the domain of cubic crystalline ice Ic (1997)

Banham, S. F. ; Jenniskens, P. ; Blake, D. F. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: Vapor-deposited amorphous water ice when warmed above the glass transition temperature (120-140 K), is a viscous liquid which exhibits a viscosity vs temperature relationship different from that of liquid water at room temperature. New studies of thin water ice films now demonstrate that viscous liquid water persists in the temperature range 140-210 K. where it coexists with cubic crystalline ice. The liquid character of amorphous water above the glass transition is demonstrated by (1) changes in the morphology of water ice films on a nonwetting surface observed in transmission electron microscopy (TEM) at around 175 K during slow warming, (2) changes in the binding energy of water molecules measured in temperature programmed desorption (TPD) studies, and (3) changes in the shape of the 3.07 micrometers absorption band observed in grazing angle reflection-absorption infrared spectroscopy (RAIRS) during annealing at high temperature. whereby the decreased roughness of the water surface is thought to cause changes in the selection rules for the excitation of O-H stretch vibrations. Because it is present over such a wide range of temperatures, we propose that this form of liquid water is a common material in nature. where it is expected to exist in the subsurface layers of comets and on the surfaces of some planets and satellites.

Keywords: Exobiology

Type: The Journal of chemical physics (ISSN 0021-9606); 107; 4; 1232-41

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High-Density Amorphous Ice, the Frost on Interstellar Grains (1995)

Blake, D. F. ; Jenniskens, P. ; Wilson, M. A. ; [et al.]

In: CASI

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Publication Date: 2019-08-16

Description: Most water ice in the universe is in a form which does not occur naturally on Earth and of which only minimal amounts have been made in the laboratory. We have encountered this 'high-density amorphous ice' in electron diffraction experiments of low-temperature (T less than 30 K) vapor-deposited water and have subsequently modeled its structure using molecular dynamics simulations. The characteristic feature of high-density amorphous ice is the presence of 'interstitial' oxygen pair distances between 3 and 4 A. However, we find that the structure is best described as a collapsed lattice of the more familiar low-density amorphous form. These distortions are frozen in at temperatures below 38 K because, we propose, it requires the breaking of one hydrogen bond, on average, per molecule to relieve the strain and to restructure the lattice to that of low-density amorphous ice. Several features of astrophysical ice analogs studied in laboratory experiments are readily explained by the structural transition from high-density amorphous ice into low-density amorphous ice. Changes in the shape of the 3.07 gm water band, trapping efficiency of CO, CO loss, changes in the CO band structure, and the recombination of radicals induced by low-temperature UV photolysis all covary with structural changes that occur in the ice during this amorphous to amorphous transition. While the 3.07 micrometers ice band in various astronomical environments can be modeled with spectra of simple mixtures of amorphous and crystalline forms, the contribution of the high-density amorphous form nearly always dominates.

Keywords: Astrophysics

Type: NASA/TM-95-207251 , NAS 1.15:207251 , The Astrophysical Journal; 455; 389-401

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