Thermal conductivity of Xe clathrate hydrate at low temperatures

Кривчиков, А. И.; Gorodilov, B. Ya.; Korolyuk, O. A.; Manzheliı̆, V. G.; Romantsova, O. O.; Conrad, Harald; Press, W.; Tse, John S.; Klug, D. D.

doi:10.1103/physrevb.73.064203

Cited by 57 publications

(61 citation statements)

References 31 publications

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“…The temperature dependence of the thermal conductivity of Xe and CH 4 is divided into four (I−IV) distinct temperature regimes. The temperature dependences in the intervals I−II (below 54 K) and IV (greater than 95 K) are similar to what is observed in tetrahydrofuran and dioxolane clathrate hydrates of structure II (Krivchikov et al 2006). The thermal conductivity grows with temperature and the curve has a shape typical for amorphous substances.…”

Section: Thermal Conductivity Of Clathratessupporting

confidence: 58%

“…However, at high temperature (170 K), the thermal conductivities of clathrates of CH 4 , Xe and tetrahydrofuran differ by only 20% (Krivchikov et al 2007). The temperature dependences of the thermal conductivity of structure I of Xe and CH 4 are similar (Krivchikov et al 2006) but are different from the ones of structure II of tetrahydrofuran, dioxolane and cyclobutanone. The temperature dependence of the thermal conductivity of Xe and CH 4 is divided into four (I−IV) distinct temperature regimes.…”

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 64%

“…The thermal conductivity grows with temperature and the curve has a shape typical for amorphous substances. In the intervals I−II (below 54 K), the temperature dependence of clathrate hydrate is only weakly dependent on the type of clathrate structure (Krivchikov et al 2006). In these intervals the thermal conductivity is practically independent on the nature of the guest molecules.…”

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 86%

“…Moreover, the thermal conductivity of the CH 4 hydrate coincides within the experimental error with the thermal conductivity of the dioxolane clathrate (Krivchikov et al 2005a,b). At present there is no theoretical model permitting a quantitative description and prediction of the thermal conductivity of clathrate hydrates in a wide range of temperatures (Krivchikov et al 2006). Thus, in the absence of more data on the thermal conductivity of single and MG clathrates, we adopt the temperature-dependent thermal conductivity of the methane clathrate given in Table 3 and use it independently of the clathrate composition.…”

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 99%

“…There are limited data on the conductivity of clathrates at low temperatures. Their thermal conductivity has been measured on gas hydrates of structure I as CH 4 (Krivchikov et al 2005a), Xe (Handa & Cook 1987;Krivchikov et al 2006) and ethylene oxide (Cook & Laubitz 1983), and gas hydrates of structure II as tetrahydrofuran (Ross & Andersson 1982;Tse & White 1988;Andersson & Suga 1996;Krivchikov et al 2005b), dioxolane (Andersson & Ross 1983;Ahmad & Phillips 1987) and cyclobutanone (Andersson & Ross 1983) in a wide range of temperatures. It is very challenging to measure the bulk thermal conductivity of a homogeneous continuous solid (Krivchikov et al 2007).…”

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 99%

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A cometary nucleus model taking into account all phase changes of water ice: amorphous, crystalline, and clathrate

Marboeuf

Schmitt

Petit

et al. 2012

A&A

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Context. Current theories, models of cometary nuclei and of ice formation in the protoplanetary disk, and laboratory studies suggest that cometary materials could be formed of pure crystalline water ice, amorphous water ice, clathrate hydrate, or a mixture of these structures of water ice. However, current models of cometary nuclei consider only two forms of ice during the thermodynamic evolution of comets: amorphous and crystalline water ices. Aims. In this work, we have developed a model of cometary nucleus that takes into account all water ice structures and phase changes in order to predict the outgassing profile of volatile molecules that could be measured by the Rosetta mission and can be used to constrain the structural type of ice existing in the interior of the Comet 67P/Churyumov-Gerasimenko, the target comet of the Rosetta mission, and, hopefully, its initial composition. Methods. We added the physic of formation/dissociation of clathrate hydrates in addition to others physical processes that are taken into account in models without clathrate hydrates. All thermal changes, as well as the release and trapping of gas with water phase changes are taken into account. Results. This model describes heat transmission, latent heat exchanges, all water ices structures and transitions (amorphous-to-pure crystalline, amorphous-to-clathrate hydrates and pure crystalline-to-clathrate hydrates and vise versa), sublimation/recondensation of volatile molecules in the nucleus, gas diffusion, gas released and trapped by crystallization and clathrate formation/dissociation processes, as well as gas and dust release and mantle formation at the surface. Applying this model to the comet 67P/ChuryumovGerasimenko, results show different outgassing profiles of volatiles molecules from the nucleus depending on the water ice structure, the distribution of volatile molecules between the "trapped" and "condensed" states in the nucleus and the thermal inertia of its porous matrix. Conclusions. Given these results, we pretend that this model is able to constrain the water ice structure and chemical composition in comets from outgassing profiles of volatile molecules, and especially those of the target comet of the Rosetta mission.

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Section: Thermal Conductivity Of Clathratessupporting

confidence: 58%

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 64%

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 86%

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 99%

Section: Thermal Conductivity Of Clathratesmentioning

confidence: 99%

See 3 more Smart Citations

A cometary nucleus model taking into account all phase changes of water ice: amorphous, crystalline, and clathrate

Marboeuf

Schmitt

Petit

et al. 2012

A&A

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Computational Techniques in the Study of the Properties of Clathrate Hydrates

Tse¹

2015

Reviews in Computational Chemistry

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Thermal Properties of Methane Hydrate by Experiment and Modeling and Impacts Upon Technology

Warzinski¹,

Gamwo²,

Rosenbaum³

et al. 2016

Alternative Energy and Shale Gas Encyclopedia

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Thermal properties of pure methane hydrate, under conditions similar to naturally occurring hydrate-bearing sediments being considered for potential production, have been determined both by a new experimental technique and by advanced molecular dynamics simulation (MDS). A novel single-sided, Transient Plane Source (TPS) technique has been developed and used to measure thermal conductivity and thermal diffusivity values of low-porosity methane hydrate formed in the laboratory. The experimental thermal conductivity data are closely matched by results from an equilibrium MDS method using in-plane polarization of the water molecules. MDS was also performed using a non-equilibrium model with a fully polarizable force field for water. The calculated thermal conductivity values from this latter approach were similar to the experimental data. The impact of thermal conductivity on gas production from a hydrate-bearing reservoir was also evaluated using the Tough+/Hydrate reservoir simulator.

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Thermal conductivity of Xe clathrate hydrate at low temperatures

Cited by 57 publications

References 31 publications

A cometary nucleus model taking into account all phase changes of water ice: amorphous, crystalline, and clathrate

A cometary nucleus model taking into account all phase changes of water ice: amorphous, crystalline, and clathrate

Computational Techniques in the Study of the Properties of Clathrate Hydrates

Thermal Properties of Methane Hydrate by Experiment and Modeling and Impacts Upon Technology

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