The cages, dynamics, and structuring of incipient methane clathrate hydrates

Walsh, Matthew; Rainey, J. Daniel; Lafond, Patrick G.; Park, Da-Hye; Beckham, Gregg T.; Jones, Michael D.; Lee, Kun‐Hong; Koh, Carolyn A.; Sloan, E. Dendy; Wu, David T.; Sum, Amadeu K.

doi:10.1039/c1cp21899a

Cited by 138 publications

(166 citation statements)

References 57 publications

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“…For instance, in simulations it is quite commonly observed that in addition to the thermodynamically stable phase that is observed during synthetic procedures other metastable hydrate phases are formed [46,47,36], in agreement to the appearance of mixed phases in modeling studies. In other experiments where nucleation and growth takes place rather slowly (min/h), cage populations can be measured as a function of time.…”

Section: Nucleationmentioning

confidence: 60%

See 1 more Smart Citation

Some current challenges in clathrate hydrate science: Nucleation, decomposition and the memory effect

Ripmeester

Alavi

2016

Current Opinion in Solid State and Materials Science

137

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Vous avez des questions? Nous pouvons vous aider. Pour communiquer directement avec un auteur, consultez la première page de la revue dans laquelle son article a été publié afin de trouver ses coordonnées. Si vous n'arrivez pas à les repérer, communiquez avec nous à PublicationsArchive-ArchivesPublications@nrc-cnrc.gc.ca. Questions? Contact the NRC Publications Archive team atPublicationsArchive-ArchivesPublications@nrc-cnrc.gc.ca. If you wish to email the authors directly, please see the first page of the publication for their contact information. NRC Publications Archive Archives des publications du CNRCThis publication could be one of several versions: author's original, accepted manuscript or the publisher's version. / La version de cette publication peut être l'une des suivantes : la version prépublication de l'auteur, la version acceptée du manuscrit ou la version de l'éditeur. NRC Publications Record / Notice d'Archives des publications de CNRC:http://nparc.cisti-icist.nrc-cnrc.gc.ca/eng/view/object/?id=dbb87be9-a830-40b5-966c-3a5334a8fe14 http://nparc.cisti-icist.nrc-cnrc.gc.ca/fra/voir/objet/?id=dbb87be9-a830-40b5-966c-3a5334a8fe14 Among outstanding issues still to be understood regarding the clathrate hydrates are the mechanism of the processes involved in the formation and decomposition of clathrates: nucleation, decomposition, and the memory effect during reformation. The latter involves the shorter induction times required for solutions of decomposed hydrate to nucleate as compared to those for freshly prepared solutions. The formation of the clathrate hydrate phases of insoluble gases in water is accompanied by a $6000 fold concentration of the gas content in the solid phase compared to the aqueous phase from which it forms. The nucleation mechanism for the solid hydrate which allows the delivery of such high concentration of gas and water in one location has been the subject of much experimental and computational study. While these studies have improved our understanding of the nucleation process, many unknown aspects remain. These developments are described in this Opinion.

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Section: Nucleationmentioning

confidence: 60%

“…2 [35]. Recent work demonstrated that the stable sI clathrate hydrate structure can be obtained from some trajectories of the homogeneous nucleation simulation [36,37]. Increased curvature of the water-gas interface was shown to increase the rate of clathrate hydrate nucleation [30].…”

Section: Nucleationmentioning

confidence: 99%

Some current challenges in clathrate hydrate science: Nucleation, decomposition and the memory effect

Ripmeester

Alavi

2016

Current Opinion in Solid State and Materials Science

137

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“…5,28,29 Radhakrishnan and Trout defined a further order parameter based on the number of guests at a suitable distance from the central one, i.e., within the domain of the first peak of the guest-guest pair correlation function of hydrates. 4 Further, geometric hydrate-liquid recognition criteria have focussed on identification of hydrate-like cavities, either polyhedral (i.e., 5 12 , 5 12 6 2 , 5 12 6 3 , or 5 12 6 4 ) 10,16,30,31 or halfpolyhedral (i.e., 5 6 , 5 6 6 1 , or 5 6 6 2 ). 32 Chakraborty et al defined Voronoi tessellation of the space centred around guest molecules.…”

Section: Introductionmentioning

confidence: 99%

Clathrate structure-type recognition: Application to hydrate nucleation and crystallisation

Lauricella

Meloni

Liang

et al. 2015

The Journal of Chemical Physics

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For clathrate-hydrate polymorphic structure-type (sI versus sII), geometric recognition criteria have been developed and validated. These are applied to the study of the rich interplay and development of both sI and sII motifs in a variety of hydrate-nucleation events for methane and H2S hydrate studied by direct and enhanced-sampling molecular dynamics (MD) simulations. In the case of nucleation of methane hydrate from enhanced-sampling simulation, we notice that already at the transition state, ∼80% of the enclathrated CH4 molecules are contained in a well-structured (sII) clathrate-like crystallite. For direct MD simulation of nucleation of H2S hydrate, some sI/sII polymorphic diversity was encountered, and it was found that a realistic dissipation of the nucleation energy (in view of non-equilibrium relaxation to either microcanonical (NVE) or isothermal-isobaric (NPT) distributions) is important to determine the relative propensity to form sI versus sII motifs.

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“…Ice nuclei are almost solely comprised of double-diamond and hexagonal water cages as illustrated in figures 5 and 6 of ref. 19, whereas hydrate nuclei contain many more different types of water cages (25,26,35). From the perspective of combinatorics, there are many more possible hydrogen-bond structures for hydrate nuclei than there are for ice nuclei.…”

mentioning

confidence: 99%

Evidence from mixed hydrate nucleation for a funnel model of crystallization

Hall

Carpendale

Kusalik

2016

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

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The molecular-level details of crystallization remain unclear for many systems. Previous work has speculated on the phenomenological similarities between molecular crystallization and protein folding. Here we demonstrate that molecular crystallization can involve funnel-shaped potential energy landscapes through a detailed analysis of mixed gas hydrate nucleation, a prototypical multicomponent crystallization process. Through this, we contribute both: (i) a powerful conceptual framework for exploring and rationalizing molecular crystallization, and (ii) an explanation of phenomenological similarities between protein folding and crystallization. Such funnel-shaped potential energy landscapes may be typical of broad classes of molecular ordering processes, and can provide a new perspective for both studying and understanding these processes. nucleation | gas clathrate hydrates | potential energy landscapes | crystallization funnel | molecular dynamics simulation M olecular crystallization and its inhibition are important to a broad range of fields. For example, some organisms [such as Antarctic fish (1) and winter rye (2)] have developed a rich chemistry of antifreeze proteins to control internal freezing, and there is significant interest in exploiting antifreeze proteins for food applications (e.g., see ref.3). Gas hydrate formation in oil and gas pipelines is a major industrial concern (4). For pharmaceuticals, there is much interest in understanding and controlling crystal polymorphism (e.g., see ref. 5). A better understanding of molecular crystallization, and factors influencing these processes, has potential to aid further advancements in such fields. As highlighted by a recent review on crystallization (6), traditional theoretical models of crystallization (e.g., classical nucleation theory) have proven to be problematic for a variety of systems and there remain technical challenges to studying crystallization both experimentally and computationally, so a clear understanding of crystal nucleation has yet to emerge.Molecular crystallization is one of the major classes of molecular ordering processes. Other molecular ordering processes include micelle formation, the formation of coordination polymers, and protein folding. Previous work has asserted, although not substantiated, that crystallization and protein folding are somehow similar processes. For example, protein folding has been speculatively described as a first-order phase transition similar to liquidsolid transitions (7). It has also been proposed that both the waterice transition and protein folding are difficult to study in silico because both are complex searches for relatively few ordered structures among numerous disordered alternative structures (8). The aim of this study is twofold: (i) to provide a conceptual description of molecular crystallization (simply referred to as crystallization henceforth), and (ii) to provide an explanation of the apparent similarities between crystallization and protein folding. On the basis of extensive simulati...

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The cages, dynamics, and structuring of incipient methane clathrate hydrates

Cited by 138 publications

References 57 publications

Some current challenges in clathrate hydrate science: Nucleation, decomposition and the memory effect

Some current challenges in clathrate hydrate science: Nucleation, decomposition and the memory effect

Clathrate structure-type recognition: Application to hydrate nucleation and crystallisation

Evidence from mixed hydrate nucleation for a funnel model of crystallization

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