Thermodynamic model of quasiliquid formation on H2O ice: Comparison with experiment

Henson, B. F.; Voss, Laura F.; Wilson, Kevin R.; Robinson, Jeanne M.

doi:10.1063/1.2056541

Cited by 30 publications

(24 citation statements)

References 35 publications

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“…16), which is consistent with theoretical predictions based on molecular dynamics calculations (e.g. Girardet and Toubin, 2001), wetting theory (Dash et al, 2006;Petrenko and Whitworth, 1999), or multimolecular adsorption (Henson, 2005). Recently have used molecules and chemical processes to probe the very surface of the QLL.…”

Section: Current Approaches To Model Snow Photochemistrysupporting

confidence: 77%

Snow physics as relevant to snow photochemistry

et al. 2008

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Abstract. Snow on the ground is a complex multiphase photochemical reactor that dramatically modifies the chemical composition of the overlying atmosphere. A quantitative description of the emissions of reactive gases by snow requires knowledge of snow physical properties. This overview details our current understanding of how those physical properties relevant to snow photochemistry vary during snow metamorphism. Properties discussed are density, specific surface area, thermal conductivity, permeability, gas diffusivity and optical properties. Inasmuch as possible, equations to parameterize these properties as functions of climatic variables are proposed, based on field measurements, laboratory experiments and theory. The potential of remote sensing methods to obtain information on some snow physical variables such as grain size, liquid water content and snow depth are discussed. The possibilities for and difficulties of building a snow photochemistry model by adapting current snow physics models are explored. Elaborate snow physics models already exist, and including variables of particular interest to snow photochemistry such as light fluxes and specific surface area appears possible. On the other hand, understanding the nature and location of reactive molecules in snow seems to be the greatest difficulty modelers will have to face for lack of experimental data, and progress on this aspect will require the detailed study of natural snow samples.

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Section: Current Approaches To Model Snow Photochemistrysupporting

confidence: 77%

Snow physics as relevant to snow photochemistry

et al. 2008

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“…This is a well-established phenomenon in surface physics of ice (Frenkel, 1946;Henson and Robinson, 2004;Henson et al, 2005;Hobbs, 2010) and other solid materials such as colloids (Alsayed et al, 2005), ceramics (Clarke, 1987), and metals (Frenken and van der Veen, 1985). Henson and Robinson (2004) have compiled studies of this phenomenon for different materials that span triplepoint temperatures from 25 to 933 K, illustrating that surface disorder is a ubiquitous property of crystals (Fig.…”

Section: Structure Of the Snow Surfacementioning

confidence: 97%

A review of air–ice chemical and physical interactions (AICI): liquids, quasi-liquids, and solids in snow

et al. 2014

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Abstract. Snow in the environment acts as a host to rich chemistry and provides a matrix for physical exchange of contaminants within the ecosystem. The goal of this review is to summarise the current state of knowledge of physical processes and chemical reactivity in surface snow with relevance to polar regions. It focuses on a description of impurities in distinct compartments present in surface snow, such as snow crystals, grain boundaries, crystal surfaces, and liquid parts. It emphasises the microscopic description of the ice surface and its link with the environment. Distinct differences between the disordered air–ice interface, often termed quasi-liquid layer, and a liquid phase are highlighted. The reactivity in these different compartments of surface snow is discussed using many experimental studies, simulations, and selected snow models from the molecular to the macro-scale. Although new experimental techniques have extended our knowledge of the surface properties of ice and their impact on some single reactions and processes, others occurring on, at or within snow grains remain unquantified. The presence of liquid or liquid-like compartments either due to the formation of brine or disorder at surfaces of snow crystals below the freezing point may strongly modify reaction rates. Therefore, future experiments should include a detailed characterisation of the surface properties of the ice matrices. A further point that remains largely unresolved is the distribution of impurities between the different domains of the condensed phase inside the snowpack, i.e. in the bulk solid, in liquid at the surface or trapped in confined pockets within or between grains, or at the surface. While surface-sensitive laboratory techniques may in the future help to resolve this point for equilibrium conditions, additional uncertainty for the environmental snowpack may be caused by the highly dynamic nature of the snowpack due to the fast metamorphism occurring under certain environmental conditions. Due to these gaps in knowledge the first snow chemistry models have attempted to reproduce certain processes like the long-term incorporation of volatile compounds in snow and firn or the release of reactive species from the snowpack. Although so far none of the models offers a coupled approach of physical and chemical processes or a detailed representation of the different compartments, they have successfully been used to reproduce some field experiments. A fully coupled snow chemistry and physics model remains to be developed.

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“…This elaboration of CNT predicts a reduction in the nucleation barrier height with the free energy of interfacial curvature (McGraw and Laaksonen, 1997). The diffuse droplet model, i.e., droplets in which the interface has a smoothly varying density profile and a finite thickness, is consistent with the gas-to-amorphous or even gas-to-crystal transition of water, as even the interface of ice particles appears to have a quasi-liquid interfacial layer of finite thickness (Henson et al, 2005). We performed molecular dynamics (MD) simulations of water clusters at the mesospheric conditions using the method utilized in (Zasetsky et al, 2007).…”

Section: Gas-to-amorphous Nucleation (Laaksonen -Mcgraw Formulation)mentioning

confidence: 99%

Thermodynamics of homogeneous nucleation of ice particles in the polar summer mesosphere

2009

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Abstract. We present the hypothesis of homogeneous nucleation of ice nano-particles in the polar summer mesosphere. The nucleation of condensed phase is traced back to the first step on the formation pathway, which is assumed to be the transition of water vapor to amorphous cluster. Amorphous clusters then freeze into water ice, likely metastable cubic ice, when they reach the critical size. The estimates based on the equilibrium thermodynamics give the critical size (radius) of amorphous water clusters as about 1.0 nm. The same estimates for the final transition step, that is the transformation of cubic to hexagonal ice, give the critical size of about 15 nm at typical upper mesospheric conditions during the polar summer (temperature T =150 K, water vapor density ρ vapor =10 9 cm −3 ).

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Thermodynamic model of quasiliquid formation on H2O ice: Comparison with experiment

Cited by 30 publications

References 35 publications

Snow physics as relevant to snow photochemistry

Snow physics as relevant to snow photochemistry

A review of air–ice chemical and physical interactions (AICI): liquids, quasi-liquids, and solids in snow

Thermodynamics of homogeneous nucleation of ice particles in the polar summer mesosphere

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