Ab Initio Studies on the Clathrate Hydrates of Some Nitrogen- and Sulfur-Containing Gases

Sun, Ning-Chen; Li, Zewen; Qiu, Nianxiang; Yu, Xiaohui; Zhang, Xuran; Li, Yanjun; Yang, Longbin; Luo, Kan; Huang, Qing; Du, Shiyu

doi:10.1021/acs.jpca.6b11850

Cited by 19 publications

(25 citation statements)

References 51 publications

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“…It is consistent with the results of the structural analysis of sII hydrates; the shape and volume of the empty 5 12 cages adjust with 5 12 6 4 cages, which occupy guest molecules, such as tetrahydrofuran (THF: C 4 H 8 O) and cyclopentane (CP: C 5 H 10 ) to stabilize sII hydrate structure . The host–guest interaction energy or lattice distortion associated with guest species has been predicted based on theoretical calculations; − hence, further computational analyses may elucidate the correlation between the volumes of host cages and the stability of sI hydrate structures. In addition, these investigations may provide insight into guest-dependent physical properties, such as the mechanical properties, of gas hydrates.…”

Section: Resultssupporting

confidence: 82%

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction

Takeya

Hachikubo

2021

J. Phys. Chem. C

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This study investigated the crystal structure and composition of C 2 H 4 hydrate, prepared from finely powdered ice and C 2 H 4 gas, using powder X-ray diffraction (PXRD). A crystallographic structural model of C 2 H 4 hydrate, derived using the Rietveld and direct-space methods, shows that the occupancy of the 5 12 cages is 38%, assuming that the 5 12 6 2 cages are fully occupied. Furthermore, similar to C 2 H 6 hydrate, the centers of guest molecules (C 2 H 4 ) lie out of the centers of the equatorial planes of the 5 12 6 2 cages and near the centers of the 5 12 cages (carbon atoms are spherically arranged around these cores). However, the 5 12 and 5 12 6 2 cages of C 2 H 4 hydrate are larger and smaller, respectively, than the corresponding cages of C 2 H 6 hydrate, despite the fact that C 2 H 4 molecules are slightly smaller than C 2 H 6 molecules. This difference is attributed to the high occupancy of the 5 12 cages of C 2 H 4 hydrate, which leads to the expansion and concomitant contraction of the 5 12 and 5 12 6 2 cages, respectively. Evidently, the relative distortion of the 5 12 6 2 and 5 12 cages of the three-dimensional sI hydrate is a crucial factor determining its stability. In addition, the kinetic stability of C 2 H 4 hydrate under low-temperature conditions was investigated by temperature-dependent PXRD.

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Section: Resultssupporting

confidence: 82%

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction

Takeya

Hachikubo

2021

J. Phys. Chem. C

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“…26 The structures of the water cages used for the study of the complexes TMAO:(H 2 O) 20 and TMAO:(H 2 O) 24 were taken from the literature. 27,28 The main QTAIM topological features of the species herein discussed are presented in Supporting Information S1-S10, and the Cartesian Coordinates of all the complexes are given in Supporting Information S11.…”

Section: Methodsmentioning

confidence: 99%

“…For this study, two water cages were considered: 5 12 and 5 12 6 2 water cages constituting elementary assemblies of some water clathrates. 27 The energy of the encapsulation (E encapsulation ) was calculated as the difference between the sum of the energies of the isolated water cage and the TMAO on the one hand, and the energy of the TMAO@(H 2 O) 20,24 , on the other hand. The D0 was calculated from the most stable (H 2 O) 20,24 isomers.…”

Section: Encapsulationmentioning

confidence: 99%

What is the hydrophobic interaction contribution to the stabilization of micro-hydrated complexes of trimethylamine oxide (TMAO)? A joint DFT-D, QTAIM, and MESP study

2019

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Micro-hydrated trimethylamine oxide (TMAO) has been investigated using a rangeseparated-hybrid functional including empirical dispersion correction. Electrophilic and nucleophilic sites on TMAO and water clusters have been identified using the molecular electrostatic potential (MESP). The nature of the chemical bonding in the different isomers of the micro-hydrated complexes has been investigated with the topological analysis of the electron density (QTAIM) method. For complexes containing one to four water molecules, the strongest intermolecular interactions consist in hydrogen bonding between the oxygen atom of the TMAO and hydrogen atoms of water molecules. From five water molecules, interactions between water molecules become the main source of stabilization of the most stable isomer. From four stationary points corresponding to the 1:1 (TMAO:H 2 O) complex, we determined the minimum distances between water molecules and central TMAO allowing the latter molecule to be encapsulated within a water clathrate-type cage. Optimization of TMAO encapsulated within two water cages (5 12 and 5 12 6 2) suggests that only in the case of the 5 12 6 2 water cage the insertion of TMAO, the preservation of the hydrogen bonding between water molecules is energetically favorable. The interaction energy between one inserted TMAO and the 5 12 6 2 water cage was calculated to be around 150 kJ/mol with respect to the ground state of two partners. This result suggest that a thorough investigation of mono-hydrated complexes may be particularly relevant to identify the most suitable water cage for encapsulating a given solute.

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“…Mondal and Chattaraj used ab initio molecular dynamics (AIMD) via atom-centered density matrix propagation (ADMP) methodologies to study time-dependent structural behavior of noble gas hydrates on the timescale of ~500 fs [36]. Sun et al carried out DFT calculations using the M06-2X method to determine the relative stabilities of guest species in various clathrate hydrate host sites [37]. They predict that the guest molecules N 2 and NO are more stable in a 5 12 cage.…”

Section: Models Of Thermodynamics Structure and Dynamics Including mentioning

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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Ab Initio Studies on the Clathrate Hydrates of Some Nitrogen- and Sulfur-Containing Gases

Cited by 19 publications

References 51 publications

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction

What is the hydrophobic interaction contribution to the stabilization of micro-hydrated complexes of trimethylamine oxide (TMAO)? A joint DFT-D, QTAIM, and MESP study

Clathrate Hydrates

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Ab Initio Studies on the Clathrate Hydrates of Some Nitrogen- and Sulfur-Containing Gases

Cited by 19 publications

References 51 publications

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C2H4 Hydrate by Powder X-ray Diffraction

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C2H4 Hydrate by Powder X-ray Diffraction

What is the hydrophobic interaction contribution to the stabilization of micro-hydrated complexes of trimethylamine oxide (TMAO)? A joint DFT-D, QTAIM, and MESP study

Clathrate Hydrates

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Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction

Distortion of the Host Water Cages of Structure I Gas Hydrates: Structural Analysis of C₂H₄ Hydrate by Powder X-ray Diffraction