Experimental Investigation of Gas Flow and Hydrate Formation Within the Hydrate Stability Zone

Meyer, D.; Flemings, Peter B.; DiCarlo, David A.; You, Kehua; Phillips, Stephen C.; Kneafsey, Timothy J.

doi:10.1029/2018jb015748

Cited by 33 publications

(54 citation statements)

References 72 publications

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“…This model was conceptually described by Ginsburg () and Soloviev and Ginsburg () and is similar to the hydrate shell theory used to describe the interactions between gas and water in bubble systems (Rehder et al, ). Meyer et al () and Sahoo et al () demonstrated the presence of hydrate shells and the diffusion‐limited hydrate formation with laboratory‐controlled experiments in porous media. This model is also very similar to the coupled thermodynamic simulations of Fu et al ().…”

Section: Models Of Methane Hydrate Formation In Geological Systemsmentioning

confidence: 99%

Mechanisms of Methane Hydrate Formation in Geological Systems

You

Flemings

Malinverno

et al. 2019

Reviews of Geophysics

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Natural gas hydrate is ice‐like mixture of gas (mostly methane) and water that is widely found in sediments along the world's continental margins and within and beneath permafrost and glaciers in a near‐surface depth interval where the pressure is sufficiently high and temperature sufficiently low for gas hydrate to be stable. We categorize the myriad of geological gas hydrate deposits into five characteristic types. We then review the multiple quantitative models that have proposed to describe the genesis of these deposits and describe how each may have formed. We emphasize the importance of coupling multiphase flow (free gas and liquid water) and multicomponent reactive transport with geological history to describe the dynamical processes of gas hydrate formation and evolution in geological systems. A better insight into the kinetics of methane formation from microbial biogenesis and the processes of multiphase flow at the pore scale will advance our knowledge of how these systems form. By understanding the generation and evolution of gas hydrate through time, we will better decipher the role of gas hydrate in the carbon cycle, its potential to contribute to climate change and geohazards, and how to design optimal strategies for gas production from hydrate reservoirs.

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Section: Models Of Methane Hydrate Formation In Geological Systemsmentioning

confidence: 99%

Mechanisms of Methane Hydrate Formation in Geological Systems

You

Flemings

Malinverno

et al. 2019

Reviews of Geophysics

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162

110

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Section: Special Section Themesmentioning

confidence: 99%

“…The role of a vapor phase in the nucleation and accumulation of gas hydrate in porous media is the focus of several laboratory studies in the Special Section as well (Meyer, Flemings, & DiCarlo, , Meyer, Flemings, DiCarlo, You, et al, ; Sahoo et al, ). Both Meyer, Flemings, DiCarlo, You, et al () and Sahoo et al () describe experiments in which gas hydrate does not form to saturations as high as are predicted based on thermodynamic equilibrium for the three phase system (gas‐pore fluid‐gas hydrate). Meyer, Flemings, DiCarlo, You, et al () start with methane migrating through the sediment sample already held within the P‐T conditions for hydrate stability, whereas Sahoo et al () inject methane gas and then allow the system to equilibrate before lowering the temperature, following a method first described by (Waite et al, ).…”

Section: Special Section Themesmentioning

confidence: 99%

“…Both Meyer, Flemings, DiCarlo, You, et al () and Sahoo et al () describe experiments in which gas hydrate does not form to saturations as high as are predicted based on thermodynamic equilibrium for the three phase system (gas‐pore fluid‐gas hydrate). Meyer, Flemings, DiCarlo, You, et al () start with methane migrating through the sediment sample already held within the P‐T conditions for hydrate stability, whereas Sahoo et al () inject methane gas and then allow the system to equilibrate before lowering the temperature, following a method first described by (Waite et al, ). These studies and Meyer, Flemings, and DiCarlo () postulate that gas hydrate initially forms as a film or skin around gas bubbles in pore spaces.…”

Section: Special Section Themesmentioning

confidence: 99%

“…Meyer, Flemings, and DiCarlo () interpret this finding by noting that lower methane flux allows more time for hydrate growth and the formation of thicker hydrate skins on gas bubbles, but also larger pressure differentials. The laboratory studies (Meyer, Flemings, & DiCarlo, , Meyer, Flemings, DiCarlo, You, et al, ; Sahoo et al, ) imply that gas bubbles may sometimes be stranded within pore space, armored by hydrate skins, and therefore unconnected to the flow of pore fluid and gas through the medium. Like the dissolved phase models of VanderBeek and Rempel (), the laboratory experiments conducted by Meyer, Flemings, & DiCarlo, (), Meyer, Flemings, DiCarlo, You, et al, () and Sahoo et al () with a free gas phase can provide an explanation, albeit with a different physical grounding, for high saturations of gas hydrate forming far above the base of the GHSZ.…”

Section: Special Section Themesmentioning

confidence: 99%

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Introduction to Special Issue on Gas Hydrate in Porous Media: Linking Laboratory and Field‐Scale Phenomena

2019

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The proliferation of drilling expeditions focused on characterizing natural gas hydrate as a potential energy resource has spawned widespread interest in gas hydrate reservoir properties and associated porous media phenomena. Between 2017 and 2019, a Special Section of this journal compiled contributed papers elucidating interactions between gas hydrate and sediment based on laboratory, numerical modeling, and field studies. Motivated mostly by field observations in the northern Gulf of Mexico and offshore Japan, several papers focus on the mechanisms for gas hydrate formation and accumulation, particularly with vapor phase gas, not dissolved gas, as the precursor to hydrate. These studies rely on numerical modeling or laboratory experiments using sediment packs or benchtop micromodels. A second focus of the Special Section is the role of fines in inhibiting production of gas from methane hydrate, controlling the distribution of hydrate at a pore scale, and influencing the bulk behavior of seafloor sediments. Other papers fill knowledge gaps related to the physical properties of hydrate‐bearing sediments and advance new approaches in coupled thermal‐mechanical modeling of these sediments during hydrate dissociation. Finally, one study addresses the long‐standing question about the fate of methane hydrate at the molecular level when CO2 is injected into natural reservoirs under hydrate‐forming conditions.

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Crystallization Mechanisms and Rates of Cyclopentane Hydrates Formation in Brine

et al. 2019

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Clathrate hydrates most often grow at the interface between liquid water and another fluid phase (hydrocarbon) acting as a provider for the hydrate guest molecules, and some transfer through this shell is required for the hydrate growth to proceed, thus self-limiting the reaction rate. An optical microscope and a horizontal reaction cell are utilized to capture the shell growth phenomenology and to estimate the hydrate layer growth rates from sequential pictures. Cyclopentane (CP) is chosen as the hydrate-forming molecule to obtain hydrates at low pressure. Experimental hydrate layer growth rates are provided for the CP+brine system, using various combinations of salts and degrees of subcooling.

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Experimental Investigation of Gas Flow and Hydrate Formation Within the Hydrate Stability Zone

Cited by 33 publications

References 72 publications

Mechanisms of Methane Hydrate Formation in Geological Systems

Mechanisms of Methane Hydrate Formation in Geological Systems

Introduction to Special Issue on Gas Hydrate in Porous Media: Linking Laboratory and Field‐Scale Phenomena

Crystallization Mechanisms and Rates of Cyclopentane Hydrates Formation in Brine

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