Abstract
The global occurrences of natural gas hydrates lead to the conclusion that tremendous amounts of hydrocarbons are bonded in these hydrate-bearing sediments, serving as a potential energy resource. For the release of the hydrate-bonded CH4 from these reservoirs, different production methods have been developed during the last decades. Among them, the chemical stimulation via injection of CO2 is considered as carbon neutral on the basis of the assumption that the hydrate-bonded CH4 is replaced by CO2. For the investigation of the replacement process of hydrate-bonded CH4 with CO2 on a µm-scale, we performed time-resolved in situ Raman spectroscopic measurements combined with microscopic observations, exposing the CH4 hydrates to a CO2 gas phase at 3.2 MPa and 274 K. Single-point Raman measurements, line scans and Raman maps were taken from the hydrate phase. Measurements were performed continuously at defined depths from the surface into the core of several hydrate crystals. Additionally, the changes in composition in the gas phase were recorded. The results clearly indicated the incorporation of CO2 into the hydrate phase with a concentration gradient from the surface to the core of the hydrate particle, supporting the shrinking core model. Microscopic observations, however, indicated that all the crystals changed their surface morphology when exposed to the CO2 gas. Some crystals of the initial CH4 hydrate phase grew or were maintained while at the same time other crystals decreased in sizes and even disappeared over time. This observation suggested a reformation process similar to Ostwald ripening rather than an exchange of molecules in already existing hydrate structures. The experimental results from this work are presented and discussed in consideration of the existing models, providing new insights on a µm-scale into the transformation process of CH4 hydrates to CO2-rich mixed hydrates.
Highlights
Natural gas hydrates are non-stoichiometric crystalline inclusion compounds where the hydrogenbonded water molecules form a three-dimensional framework of water cavities
The transformation process of pure CH4 hydrates into CO2 -rich mixed hydrates was unveiled in this study on a μm scale by use of time-resolved in situ Raman spectroscopic measurements and microscopic observations
The results from the Raman spectroscopic measurements clearly indicated the incorporation of CO2 into the hydrate phase with a concentration gradient at different penetration depths rather than the growth of a CO2 layer on the existing CH4 hydrate crystal
Summary
Natural gas hydrates are non-stoichiometric crystalline inclusion compounds where the hydrogenbonded water molecules form a three-dimensional framework of water cavities. The widespread global occurrence and the high energy density of natural gas hydrates lead to the assumption that large amounts of natural gas, predominantly CH4 , are stored in natural gas hydrate deposits/reservoirs [3,4,5]. Motivated by their potential as a future energy source, exploration and production of CH4 from natural gas hydrates are attracting considerable attention.
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