Examination of Hydrate Formation Methods: Trying to Create Representative Samples

Forming representative gas hydrate-bearing laboratory samples is important so that the properties of these materials may be measured, while controlling the composition and other variables. Natural samples are rare, and have often experienced pressure and temperature changes that may affect the prope...

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Bibliographic Details
Main Authors: Kneafsey, T.J., Rees, E.V.L., Nakagawa, S., Kwon, T.-H.
Language:unknown
Published: 2012
Subjects:
03 NATURAL GAS
54 ENVIRONMENTAL SCIENCES
58 GEOSCIENCES
CARBON DIOXIDE
CAT SCANNING
GAS HYDRATES
GASES
HYDRATES
HYPOTHESIS
IMPLEMENTATION
KAOLINITE
MELTING
METHANE
MIXTURES
MODIFICATIONS
NATURAL GAS
NUCLEATION
PHYSICS
SAND
SATURATION
SILICA GEL
WATER
WATER SATURATION
Methane hydrate
Online Access:http://www.osti.gov/servlets/purl/1050730
https://www.osti.gov/biblio/1050730
https://doi.org/10.2172/1050730
Description
Summary:Forming representative gas hydrate-bearing laboratory samples is important so that the properties of these materials may be measured, while controlling the composition and other variables. Natural samples are rare, and have often experienced pressure and temperature changes that may affect the property to be measured [Waite et al., 2008]. Forming methane hydrate samples in the laboratory has been done a number of ways, each having advantages and disadvantages. The ice-to-hydrate method [Stern et al., 1996], contacts melting ice with methane at the appropriate pressure to form hydrate. The hydrate can then be crushed and mixed with mineral grains under controlled conditions, and then compacted to create laboratory samples of methane hydrate in a mineral medium. The hydrate in these samples will be part of the load-bearing frame of the medium. In the excess gas method [Handa and Stupin, 1992], water is distributed throughout a mineral medium (e.g. packed moist sand, drained sand, moistened silica gel, other porous media) and the mixture is brought to hydrate-stable conditions (chilled and pressurized with gas), allowing hydrate to form. This method typically produces grain-cementing hydrate from pendular water in sand [Waite et al., 2004]. In the dissolved gas method [Tohidi et al., 2002], water with sufficient dissolved guest molecules is brought to hydrate-stable conditions where hydrate forms. In the laboratory, this is can be done by pre-dissolving the gas of interest in water and then introducing it to the sample under the appropriate conditions. With this method, it is easier to form hydrate from more soluble gases such as carbon dioxide. It is thought that this method more closely simulates the way most natural gas hydrate has formed. Laboratory implementation, however, is difficult, and sample formation is prohibitively time consuming [Minagawa et al., 2005; Spangenberg and Kulenkampff, 2005]. In another version of this technique, a specified quantity of gas is placed in a sample, then the sample is ...

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