Film Growth of Ice by Vapor Deposition at 128−185 K Studied by Fourier Transform Infrared Reflection−Absorption Spectroscopy:  Evolution of the OH Stretch and the Dangling Bond with Film Thickness

Kanan, Sofian M.; Leung, K. T.

doi:10.1021/jp0142841

Cited by 46 publications

(68 citation statements)

References 48 publications

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“…From our diffraction studies we now find that significant amounts of amorphous phase are unlikely to exist in contact with "ice I c "; earlier evidence for amorphous relics in "ice I c ", based on a simplified analysis of low-resolution diffraction data (16,39,43), should be reconsidered in the light of an appropriate model for stacking disorder and with higher-resolution data, in line with the conclusions of Mitlin and Leung (53). The situation may, however, be different for solutes at high concentration, which impede or even prevent any water crystallization at temperatures even far below the melting point (55).…”

Section: Discussionsupporting

confidence: 77%

Extent and relevance of stacking disorder in “ice I_c”

Kuhs

Sippel

Falenty

et al. 2012

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

215

280

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A solid water phase commonly known as "cubic ice" or "ice I c " is frequently encountered in various transitions between the solid, liquid, and gaseous phases of the water substance. It may form, e.g., by water freezing or vapor deposition in the Earth's atmosphere or in extraterrestrial environments, and plays a central role in various cryopreservation techniques; its formation is observed over a wide temperature range from about 120 K up to the melting point of ice. There was multiple and compelling evidence in the past that this phase is not truly cubic but composed of disordered cubic and hexagonal stacking sequences. The complexity of the stacking disorder, however, appears to have been largely overlooked in most of the literature. By analyzing neutron diffraction data with our stacking-disorder model, we show that correlations between next-nearest layers are clearly developed, leading to marked deviations from a simple random stacking in almost all investigated cases. We follow the evolution of the stacking disorder as a function of time and temperature at conditions relevant to atmospheric processes; a continuous transformation toward normal hexagonal ice is observed. We establish a quantitative link between the crystallite size established by diffraction and electron microscopic images of the material; the crystallite size evolves from several nanometers into the micrometer range with progressive annealing. The crystallites are isometric with markedly rough surfaces parallel to the stacking direction, which has implications for atmospheric sciences.

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Section: Discussionsupporting

confidence: 77%

Extent and relevance of stacking disorder in “ice I_c”

Kuhs

Sippel

Falenty

et al. 2012

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

215

280

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“…Here, we assign it to the stretching of the dangling OH bond coupled with the bending of the water molecules. 31 The existence of the dangling OH bonds suggests that the water ice deposited at 10 K was porous amorphous ice. We warmed up the amorphous ice from 10 K to 50 K at a speed of 0.5 K min -1 .…”

Section: Methodsmentioning

confidence: 99%

On the State of Water Ice on Saturn’s Moon Titan and Implications to Icy Bodies in the Outer Solar System

2009

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The crystalline state of water ice in the Solar System depends on the temperature history of the ice and the influence of energetic particles to which it has been exposed. We measured the infrared absorption spectra of amorphous and crystalline water ice in the 10-50 K and 10-140 K temperature range, respectively, and conducted a systematic experimental study to investigate the amorphization of crystalline water ice via ionizing radiation irradiation at doses of up to 160 ± 30 eV per molecule. We found that crystalline water ice can be converted only partially to amorphous ice by electron irradiation. The experiments showed that a fraction of the 1.65 µm band, which is characteristic for crystalline water ice, survived the irradiation, to a degree that strongly depends on the temperature. Quantitative kinetic fits of the temporal evolution of the 1.65 µm band clearly demonstrate that there is a balance between thermal recrystallization and irradiation-induced amorphization, with thermal recrystallizaton dominant at higher temperatures.Our experiments show the amorphization at 40K was incomplete, in contradiction to Mastrapa and Brown's conclusion (Icarus 2006, 183, 207.). At 50 K, the recrystallization due to thermal effects is strong, and most of the crystalline ice survived. Temperatures of most icy objects in the Solar System, including Jovian satellites, Saturnian satellites (including Titan), and Kuiper Belt Objects, are equal to or above 50 K; this explains why water ice detected on those objects is mostly crystalline.3

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“…The thickness of the ice film was estimated by using a procedure based on the Fresnel method, which has been given in detail in our previous work. 25 Figure 1a shows the FTIR-RA spectrum of an ice film deposited at 5.0 × 10 -7 Torr for 900 s at 123 K, which is estimated to have a film thickness of ∼6 nm from the Fresnel analysis. 25 Evidently, the spectrum is dominated by a strong broad band at 3376 cm -1 and a weaker feature at 1656 cm -1 , corresponding to the OH stretching modes and the HOH bending mode of the bulk, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…25 Figure 1a shows the FTIR-RA spectrum of an ice film deposited at 5.0 × 10 -7 Torr for 900 s at 123 K, which is estimated to have a film thickness of ∼6 nm from the Fresnel analysis. 25 Evidently, the spectrum is dominated by a strong broad band at 3376 cm -1 and a weaker feature at 1656 cm -1 , corresponding to the OH stretching modes and the HOH bending mode of the bulk, respectively. Furthermore, a sharp but considerably weaker feature at 3696 cm -1 can also be observed, which can be attributed to the OH dangling-bond mode, i.e., the OH stretching mode for which the H atom is not involved in the H-bonding.…”

Section: Methodsmentioning

confidence: 99%

Thermal Evolution of Acetic Acid Nanodeposits over 123−180 K on Noncrystalline Ice and Polycrystalline Ice Studied by FTIR Reflection−Absorption Spectroscopy: Hydrogen-bonding Interactions in Acetic Acid and between Acetic Acid and Ice

Gao

2005

J. Phys. Chem. B

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Acetic acid vapor-deposited on ultrathin noncrystalline ice (NCI) and polycrystalline ice (PCI) films (less than 6 nm thick) under ultrahigh vacuum conditions has been investigated by using Fourier Transform Infrared Reflection-Absorption Spectroscopy. Pristine acetic acid deposited at 123 K (on a copper support) appears as an amorphous solid, which undergoes an irreversible phase transformation to a more structurally ordered (polycrystalline) form upon annealing to 153 K. Acetic acid is found to adsorb on NCI and PCI films initially through hydrogen bonding between CdO and dangling OH (of ice), followed by the formation of multilayers at 123 K. Thermal evolution studies of a low exposure of acetic acid on the ultrathin NCI and PCI films show that acetic acid undergoes coevaporation with water likely as an acetic acid hydrate at 155 K, which continues until the entire ice film has been exhausted at 165 K. Above 165 K, the remaining acetic acid solid appears to evaporate without undergoing the phase transformation, in contrast to the case of a high acetic acid exposure. Coevaporation of acetic acid with water is also found to proceed at a faster rate than the subsequent evaporation of acetic acid, which is consistent with the weaker interactions observed in the H-bonded acetic acid hydrate than that in acetic acid solid.

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Film Growth of Ice by Vapor Deposition at 128−185 K Studied by Fourier Transform Infrared Reflection−Absorption Spectroscopy: Evolution of the OH Stretch and the Dangling Bond with Film Thickness

Cited by 46 publications

References 48 publications

Extent and relevance of stacking disorder in “ice I_c”

Extent and relevance of stacking disorder in “ice I_c”

On the State of Water Ice on Saturn’s Moon Titan and Implications to Icy Bodies in the Outer Solar System

Thermal Evolution of Acetic Acid Nanodeposits over 123−180 K on Noncrystalline Ice and Polycrystalline Ice Studied by FTIR Reflection−Absorption Spectroscopy: Hydrogen-bonding Interactions in Acetic Acid and between Acetic Acid and Ice

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Film Growth of Ice by Vapor Deposition at 128−185 K Studied by Fourier Transform Infrared Reflection−Absorption Spectroscopy: Evolution of the OH Stretch and the Dangling Bond with Film Thickness

Cited by 46 publications

References 48 publications

Extent and relevance of stacking disorder in “ice Ic”

Extent and relevance of stacking disorder in “ice Ic”

On the State of Water Ice on Saturn’s Moon Titan and Implications to Icy Bodies in the Outer Solar System

Thermal Evolution of Acetic Acid Nanodeposits over 123−180 K on Noncrystalline Ice and Polycrystalline Ice Studied by FTIR Reflection−Absorption Spectroscopy: Hydrogen-bonding Interactions in Acetic Acid and between Acetic Acid and Ice

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Extent and relevance of stacking disorder in “ice I_c”

Extent and relevance of stacking disorder in “ice I_c”