New silica clathrate minerals that are isostructural with natural gas hydrates

Momma, Koichi; Ikeda, Takuji; Nishikubo, Katsumi; Takahashi, Naoki; Honma, Chibune; Takada, Masayuki; Furukawa, Yoshihiro; Nagase, Toshiro; Kudoh, Yasuhiro

doi:10.1038/ncomms1196

Cited by 129 publications

(57 citation statements)

References 47 publications

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“…These polymorphs of SiO 2 , known as clathrasils, have cavities of sub‐nanometer size like zeosils (all‐silica zeolites), but with such small openings to prevent diffusion in and out of the pores;, they might thus be pictured as inert hosts for nanomaterials of zero‐dimensionality. Although melanophlogite (Figure ), contains only very small molecules, like CH 4 , CO 2 or N 2 ,,, other hydrocarbons are found in clathrasils with larger cavities:, indeed, the recently discovered chibaite hosts methane, ethane, propane and isobutane ,,…”

Section: Empty Space Architecturesmentioning

confidence: 99%

Supramolecular Organization in Confined Nanospaces

Tabacchi

2018

ChemPhysChem

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Empty spaces are abhorred by nature, which immediately rushes in to fill the void. Humans have learnt pretty well how to make ordered empty nanocontainers, and to get useful products out of them. When such an order is imparted to molecules, new properties may appear, often yielding advanced applications. This review illustrates how the organized void space inherently present in various materials: zeolites, clathrates, mesoporous silica/organosilica, and metal organic frameworks (MOF), for example, can be exploited to create confined, organized, and self-assembled supramolecular structures of low dimensionality. Features of the confining matrices relevant to organization are presented with special focus on molecular-level aspects. Selected examples of confined supramolecular assemblies - from small molecules to quantum dots or luminescent species - are aimed to show the complexity and potential of this approach. Natural confinement (minerals) and hyperconfinement (high pressure) provide further opportunities to understand and master the atomistic-level interactions governing supramolecular organization under nanospace restrictions.

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Section: Empty Space Architecturesmentioning

confidence: 99%

Supramolecular Organization in Confined Nanospaces

Tabacchi

2018

ChemPhysChem

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“…Without the guest molecule, the clathrate structure is thermodynamically unstable. There are three different types of polyhedral cages, normally formed by hydrogen-bonded water molecules: cubic sI-hydrate, cubic sII-hydrate, and hexagonal sH-hydrate (Figure 24.17) [87,88]. The size and the number of the trapped molecules (N 2 , H 2 , THF, THF + H 2 , CH 4 , CO 2 + H 2 , TBAF + H 2 , HQ + H 2 , MTBE + H 2 ) determine the structure type as well as the temperature and pressure of clathrate formation [89].…”

Section: Clathratesmentioning

confidence: 99%

“…The hydrogen capacity of the materials varies between 3.8 wt% (31 g l 1 ) for the sII-hydrate fully loaded with H 2 and 0.37 wt% (3.8 g l 1 ) for a sI-hydrate with ethylene oxide and H 2 as guest molecules [89]. Illustration taken from Reference [88]. Nature publishing group.…”

Section: Clathratesmentioning

confidence: 99%

Physics of Hydrogen

Korte

Mandt

Bergholz

2016

Hydrogen Science and Engineering : Materials, Processes, Systems and Technology

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“…The traditional use of the word clathrate in science and engineering is in reference to materials comprised of hosts that are polymers trapping guests that are atoms or molecules. However current use of this word now extends to many other molecular host systems such as calixarenes [6], cyclodextrins [7], and even to inorganic polymeric systems such as zeolites [8] and chibaites [9]. Hofmann compounds [10] and metal organic frameworks (MOFs) [11] can also serve as clathrate hosts for small aromatic guest molecules such as carbon tetrachloride, benzene, toluene, and xylene.…”

Section: Introductionmentioning

confidence: 99%

Clathrate Hydrates

Lee¹,

Kenney²

2018

Solidification

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The clathrate hydrates represent a distinctive, unusual, scientifically significant, and practically important class of solid state materials. Since their discovery in the early nineteenth century, their widespread distribution in oceans and permafrost regions and their ability to trap atoms and small molecules-particularly methane and other small hydrocarbons-has led to the realization that they are simultaneously a tremendous energy source and, in the face of global warming, a potential greenhouse gas release disaster of unprecedented magnitude just waiting to happen. In the twentieth century, it was realized that solid methane clathrate hydrate could plug natural gas pipelines and disrupt oil drilling processes. On the environmental positive side, clathrate hydrates can store hydrogen and sequester carbon dioxide. A brief historical review of the formation, structure, and uses of clathrate hydrates forms the backdrop for a discussion of modern scientific investigations of these solids employing spectroscopy, structure determination methods, isotopic studies, computational-theoretical modeling, and interrogations of guest-host interactions via special guests. For example, the use of colored halogens in clathrate hydrate hosts enables UV-visible spectroscopic methods to be employed to study clathrate hydrate structure.

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New silica clathrate minerals that are isostructural with natural gas hydrates

Cited by 129 publications

References 47 publications

Supramolecular Organization in Confined Nanospaces

Supramolecular Organization in Confined Nanospaces

Physics of Hydrogen

Clathrate Hydrates

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