Deep-Sea Field Test of the CH sub(4) Hydrate to CO sub(2) Hydrate Spontaneous Conversion Hypothesis

We have carried out a small-scale deep-sea field test of the hypothesis that CH sub(4) gas can be spontaneously produced from CH sub(4) hydrate by injection of a CO sub(2)/N sub(2) gas mixture, thereby inducing release of the encaged molecules with sequestration of the injected gas. Pressure cell st...

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Veröffentlicht in:	Energy & fuels 2014-11, Vol.28 (11), p.7061-7069
Hauptverfasser:	Brewer, Peter G, Peltzer, Edward T, Walz, Peter M, Coward, Elizabeth K, Stern, Laura A, Kirby, Stephen H, Pinkston, John
Format:	Artikel
Sprache:	eng
Schlagworte:	Carbon dioxide Cylinders Displacement Field tests Gas mixtures Hydrates Pressure vessels Water
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creator	Brewer, Peter G Peltzer, Edward T Walz, Peter M Coward, Elizabeth K Stern, Laura A Kirby, Stephen H Pinkston, John
description	We have carried out a small-scale deep-sea field test of the hypothesis that CH sub(4) gas can be spontaneously produced from CH sub(4) hydrate by injection of a CO sub(2)/N sub(2) gas mixture, thereby inducing release of the encaged molecules with sequestration of the injected gas. Pressure cell studies have shown that, under some pressure and temperature conditions, this gas mixture can induce formation of a solid N sub(2)/CO sub(2) hydrate with no associated liquid water production. We transported a cylinder of pure CH sub(4) hydrate, contained within a pressure vessel, to the sea floor at 690 m depth off shore Monterey, CA, using the remotely operated vehicle (ROV) Ventana. Upon opening the pressure vessel with the vehicle robotic arm, we emplaced the hydrate specimen on a metal stand and covered this with a glass cylinder full of a 25% CO sub(2)/75% N sub(2) gas mixture, thereby fully displacing the surrounding seawater (T = 4.92 degree C). We observed complete and rapid dissociation of the CH sub(4) hydrate with release of liquid water and creation of a mixed gas phase. This gas composition will undergo transition over time because of the high solubility of CO sub(2) in the displaced water phase. We show that the experimental outcome is critically controlled by the injected gas/hydrate/water ratio.
doi_str_mv	10.1021/ef501430h
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Pressure cell studies have shown that, under some pressure and temperature conditions, this gas mixture can induce formation of a solid N sub(2)/CO sub(2) hydrate with no associated liquid water production. We transported a cylinder of pure CH sub(4) hydrate, contained within a pressure vessel, to the sea floor at 690 m depth off shore Monterey, CA, using the remotely operated vehicle (ROV) Ventana. Upon opening the pressure vessel with the vehicle robotic arm, we emplaced the hydrate specimen on a metal stand and covered this with a glass cylinder full of a 25% CO sub(2)/75% N sub(2) gas mixture, thereby fully displacing the surrounding seawater (T = 4.92 degree C). We observed complete and rapid dissociation of the CH sub(4) hydrate with release of liquid water and creation of a mixed gas phase. This gas composition will undergo transition over time because of the high solubility of CO sub(2) in the displaced water phase. 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source	ACS Publications
subjects	Carbon dioxide Cylinders Displacement Field tests Gas mixtures Hydrates Pressure vessels Water
title	Deep-Sea Field Test of the CH sub(4) Hydrate to CO sub(2) Hydrate Spontaneous Conversion Hypothesis
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