Issue 19, 2019

Macroscopic defects upon decomposition of CO2 clathrate hydrate crystals

Abstract

Micrometer- and submicrometer-sized pores and macroscopic defects like cracks and tubular channels can be found in a variety of clathrate hydrates (hydrates for short) during formation and decomposition. Their origin, their evolution in time, and their effect on hydrate decomposition kinetics are unclear. We used time-lapse micro computed tomography (μCT) in combination with temperature control and pressure monitoring to study the formation and evolution of pores and macroscopic defects in decomposing CO2 hydrates at subzero (Celsius) temperature. Our results suggest that the decomposition of hydrates is always accompanied by the formation of pores and an increase of the apparent hydrate volume by more than 3%. Hydrate decomposition often starts with the formation of cracks inside the hydrate and not necessarily at the free surface of the hydrate, which frequently remains intact for a long period and seems to be self-preserved in some regions. Decomposition spreads out from these cracks in a uniform fashion yielding a variety of macroscopic features. In some cases, the propagating decomposition front seems to get blocked by planar barriers inside the hydrate yielding regions with high resistance against decomposition. This, together with a generally heterogeneous distribution of decomposition resistant regions, challenges the shrinking core model of hydrate decomposition as well as the popular ice-rind theory used to explain the effect of self-preservation.

Graphical abstract: Macroscopic defects upon decomposition of CO2 clathrate hydrate crystals

Supplementary files

Article information

Article type
Paper
Submitted
29 Dec 2018
Accepted
11 Apr 2019
First published
26 Apr 2019
This article is Open Access
Creative Commons BY license

Phys. Chem. Chem. Phys., 2019,21, 9694-9708

Macroscopic defects upon decomposition of CO2 clathrate hydrate crystals

S. Arzbacher, N. Rahmatian, A. Ostermann, B. Massani, T. Loerting and J. Petrasch, Phys. Chem. Chem. Phys., 2019, 21, 9694 DOI: 10.1039/C8CP07871H

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