水/甲烷界面处的气体水合物成核与笼形结构形成。

Gas hydrate nucleation and cage formation at a water/methane interface.

作者信息

Hawtin Robert W, Quigley David, Rodger P Mark

机构信息

Department of Chemistry and Centre for Scientific Computing, University of Warwick, Coventry, UK.

出版信息

Phys Chem Chem Phys. 2008 Aug 28;10(32):4853-64. doi: 10.1039/b807455k. Epub 2008 Jul 23.

DOI:10.1039/b807455k

PMID:18688529

Abstract

Nucleation of gas hydrates remains a poorly understood phenomenon, despite its importance as a critical step in understanding the performance and mode of action of low dosage hydrate inhibitors. We present here a detailed analysis of the structural and mechanistic processes by which gas hydrates nucleate in a molecular dynamics simulation of dissolved methane at a methane/water interface. It was found that hydrate initially nucleates into a phase consistent with none of the common bulk crystal structures, but containing structural units of all of them. The process of water cage formation has been found to correlate strongly with the collective arrangement of methane molecules.

摘要

尽管气体水合物的成核作为理解低剂量水合物抑制剂性能和作用方式的关键步骤至关重要，但其仍然是一个尚未被充分理解的现象。在此，我们对溶解甲烷在甲烷/水界面进行分子动力学模拟时气体水合物成核的结构和机理过程进行了详细分析。研究发现，水合物最初成核形成的相与所有常见的块状晶体结构均不一致，但包含了所有这些结构的结构单元。已发现水笼形成过程与甲烷分子的集体排列密切相关。

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水/甲烷界面处的气体水合物成核与笼形结构形成。

Gas hydrate nucleation and cage formation at a water/methane interface.

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