Methane Recovery from Hydrate-bearing Sediments

Gas hydrates are crystalline compounds made of gas and water molecules. Methane hydrates are found in marine sediments and permafrost regions; extensive amounts of methane are trapped in the form of hydrates. Methane hydrate can be an energy resource, contribute to global warming, or cause seafloor...

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Bibliographic Details
Main Authors: J. Carlos Santamarina, Costas Tsouris
Language:unknown
Published: 2012
Subjects:
03 NATURAL GAS
ALGORITHMS
BEARINGS
DEPRESSURIZATION
DISSOCIATION
DISSOLUTION
FLUID FLOW
FOCUSING
FRACTURES
GAS HYDRATES
GREENHOUSE EFFECT
HYDRATES
INSTABILITY
METHANE
PERMAFROST
PHYSICAL PROPERTIES
SALINITY
SAND
SEDIMENTS
SOLUBILITY
STABILITY
TRANSIENTS
Methane hydrate
permafrost
Online Access:http://www.osti.gov/servlets/purl/1041003
https://www.osti.gov/biblio/1041003
https://doi.org/10.2172/1041003
Description
Summary:Gas hydrates are crystalline compounds made of gas and water molecules. Methane hydrates are found in marine sediments and permafrost regions; extensive amounts of methane are trapped in the form of hydrates. Methane hydrate can be an energy resource, contribute to global warming, or cause seafloor instability. This study placed emphasis on gas recovery from hydrate bearing sediments and related phenomena. The unique behavior of hydrate-bearing sediments required the development of special research tools, including new numerical algorithms (tube- and pore-network models) and experimental devices (high pressure chambers and micromodels). Therefore, the research methodology combined experimental studies, particle-scale numerical simulations, and macro-scale analyses of coupled processes. Research conducted as part of this project started with hydrate formation in sediment pores and extended to production methods and emergent phenomena. In particular, the scope of the work addressed: (1) hydrate formation and growth in pores, the assessment of formation rate, tensile/adhesive strength and their impact on sediment-scale properties, including volume change during hydrate formation and dissociation; (2) the effect of physical properties such as gas solubility, salinity, pore size, and mixed gas conditions on hydrate formation and dissociation, and it implications such as oscillatory transient hydrate formation, dissolution within the hydrate stability field, initial hydrate lens formation, and phase boundary changes in real field situations; (3) fluid conductivity in relation to pore size distribution and spatial correlation and the emergence of phenomena such as flow focusing; (4) mixed fluid flow, with special emphasis on differences between invading gas and nucleating gas, implications on relative gas conductivity for reservoir simulations, and gas recovery efficiency; (5) identification of advantages and limitations in different gas production strategies with emphasis; (6) detailed study of CH4-CO2 exchange as a ...

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