Synchrotron X-ray computed microtomography study on gas hydrate decomposition in a sedimentary matrix

Yang, Lei; Falenty, Andrzej; Chaouachi, Marwen; Haberthür, David; Kuhs, Werner F.

doi:10.1002/2016gc006521

Cited by 205 publications

(120 citation statements)

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“…X‐ray computed tomography (CT) enables nondestructive 3‐D visualization of hydrate‐bearing sediments and is increasingly applied in the hydrate field to understand interactions between hydrate and surrounding sediments (Chaouachi et al, ; Chen & Espinoza, ; Choi et al, ; Jin et al, ; Seol & Kneafsey, ; Ta et al, ; Yang et al, ). However, methane hydrate segmentation from the surrounding pore liquid is difficult as the attenuation coefficient of methane hydrate is close to that of water.…”

Section: Introductionmentioning

confidence: 99%

“…Proper interpretation and utilization of these results heavily rely on understanding the pore habits of methane hydrate, which to date have only been indirectly determined with acoustic velocity measurements (Santamarina et al, 2015). X-ray computed tomography (CT) enables nondestructive 3-D visualization of hydrate-bearing sediments and is increasingly applied in the hydrate field to understand interactions between hydrate and surrounding sediments (Chaouachi et al, 2015;Chen & Espinoza, 2018;Choi et al, 2011;Jin et al, 2008;Seol & Kneafsey, 2009;Ta et al, 2015;Yang et al, 2016). However, methane hydrate segmentation from the surrounding pore liquid is difficult as the attenuation coefficient of methane hydrate is close to that of water.…”

Section: Introductionmentioning

confidence: 99%

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Pore‐Scale Visualization of Methane Hydrate‐Bearing Sediments With Micro‐CT

Lei

Seol

Jarvis

2018

Geophysical Research Letters

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X‐ray computed tomography (CT) has become a critical technique in the study of porous media. It has attracted growing attention for analyzing hydrate‐bearing sediment, but this has been done using surrogates (Xe/Kr) only due to difficulties in distinguishing methane hydrate from water. This study presents the successful imaging of methane hydrate coexisting with pore liquid, gas, and sediments. We used potassium iodide (KI) solutions and in‐line propagation‐based phase‐contrast CT analysis of X‐ray attenuation and diffraction to distinguish the four materials. Thus, consideration for CT‐related X‐ray physics was necessary to optimize KI concentrations, improve material separation with X‐ray propagation, and properly interpret artifacts within the images. The images clearly show methane hydrate in the pore space of sand (~250 μm) coexisting with KI solution and gas. Following this, X‐ray CT can now be used to visualize pore habits of natural methane hydrate in sediment cores.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Pore‐Scale Visualization of Methane Hydrate‐Bearing Sediments With Micro‐CT

Lei

Seol

Jarvis

2018

Geophysical Research Letters

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“…One of the possible explanations is that the intrinsic strength of methane hydrate is 20 to 30 times stronger than that of ice at a temperature near the freezing point (Durham, 2003). Moreover, water films between hydrate crusts or crystals and grain surfaces (Chaouachi et al, 2015;Yang et al, 2016), unfrozen water (Chamberlain et al, Figure 7. The determined shear strength shows the effect of hydrate bearing and freezing on shear strength.…”

Section: Physical Model Of Hydrate Reinforcement Of Sedimentsmentioning

confidence: 99%

Gas Hydrates in Permafrost: Distinctive Effect of Gas Hydrates and Ice on the Geomechanical Properties of Simulated Hydrate‐Bearing Permafrost Sediments

et al. 2019

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The geomechanical stability of the permafrost formations containing gas hydrates in the Arctic is extremely vulnerable to global warming and the drilling of wells for oil and gas exploration purposes. In this work the effect of gas hydrate and ice on the geomechanical properties of sediments was compared by triaxial compression tests for typical sediment conditions: unfrozen hydrate‐free sediments at 0.3 °C, hydrate‐free sediments frozen at −10 °C, unfrozen sediments containing about 22 vol% methane hydrate at 0.3 °C, and hydrate‐bearing sediments frozen at −10 °C. The effect of hydrate saturation on the geomechanical properties of simulated permafrost sediments was also investigated at predefined temperatures and confining pressures. Results show that ice and gas hydrates distinctively influence the shearing characteristics and deformation behavior. The presence of around 22 vol% methane hydrate in the unfrozen sediments led to a shear strength as strong as those of the frozen hydrate‐free specimens with 85 vol% of ice in the pores. The frozen hydrate‐free sediments experienced brittle‐like failure, while the hydrate‐bearing sediments showed large dilatation without rapid failure. Hydrate formation in the sediments resulted in a measurable reduction in the internal friction, while freezing did not. In contrast to ice, gas hydrate plays a dominant role in reinforcement of the simulated permafrost sediments. Finally, a new physical model was developed, based on formation of hydrate networks or frame structures to interpret the observed strengthening in the shear strength and the ductile deformation.

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“…Other compounds such as tetrahydrofuran (THF), carbon dioxide (CO 2 ), and xenon (Xe) can also form hydrates in the presence of water, and laboratory experiments often resort to these hydrate formers as alternatives to methane in order to recreate and understand hydrate phenomena in nature. Among these three most common analogs to methane hydrate, xenon hydrate has become increasingly popular as an experimental analog in recent years (Chaouachi et al, , ; Chen & Espinoza, ; Chen et al, ; Jin et al, ; Waite et al, ; Yang et al, ). There are four main reasons for this: (1) Xenon forms structure I hydrate up to 1.8 GPa (Sanloup et al, ), which is the hydrate structure commonly observed in nature; (2) xenon remains a gas phase under relevant experimental conditions (in contrast to THF, which is a liquid that is fully miscible with water and therefore poorly suited for studies of interfacial growth and multiphase dissociation of hydrate); (3) xenon is nonflammable and can be used to form hydrates under ambient temperature and moderate pressure (e.g., 24 °C and 7 MPa), experimental conditions which are easier to create and control in the laboratory relative to what is required for methane hydrate; and (4) due to its high molecular mass (131.3 g/mol), xenon gas can enhance the density contrast between gas hydrate and the aqueous solution, thus significantly improving image quality when using X‐ray computed tomography (CT).…”

Section: Introductionmentioning

confidence: 99%

Xenon Hydrate as an Analog of Methane Hydrate in Geologic Systems Out of Thermodynamic Equilibrium

Waite

Cueto‐Felgueroso

et al. 2019

Geochem Geophys Geosyst

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Methane hydrate occurs naturally under pressure and temperature conditions that are not straightforward to replicate experimentally. Xenon has emerged as an attractive laboratory alternative to methane for studying hydrate formation and dissociation in multiphase systems, given that it forms hydrates under milder conditions. However, building reliable analogies between the two hydrates requires systematic comparisons, which are currently lacking. We address this gap by developing a theoretical and computational model of gas hydrates under equilibrium and nonequilibrium conditions. We first compare equilibrium phase behaviors of the Xe·H2O and CH4·H2O systems by calculating their isobaric phase diagram, and then study the nonequilibrium kinetics of interfacial hydrate growth using a phase field model. Our results show that Xe·H2O is a good experimental analog to CH4·H2O, but there are key differences to consider. In particular, the aqueous solubility of xenon is altered by the presence of hydrate, similar to what is observed for methane; but xenon is consistently less soluble than methane. Xenon hydrate has a wider nonstoichiometry region, which could lead to a thicker hydrate layer at the gas‐liquid interface when grown under similar kinetic forcing conditions. For both systems, our numerical calculations reveal that hydrate nonstoichiometry coupled with hydrate formation dynamics leads to a compositional gradient across the hydrate layer, where the stoichiometric ratio increases from the gas‐facing side to the liquid‐facing side. Our analysis suggests that accurate composition measurements could be used to infer the kinetic history of hydrate formation in natural settings where gas is abundant.

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Synchrotron X-ray computed microtomography study on gas hydrate decomposition in a sedimentary matrix

Cited by 205 publications

References 91 publications

Pore‐Scale Visualization of Methane Hydrate‐Bearing Sediments With Micro‐CT

Pore‐Scale Visualization of Methane Hydrate‐Bearing Sediments With Micro‐CT

Gas Hydrates in Permafrost: Distinctive Effect of Gas Hydrates and Ice on the Geomechanical Properties of Simulated Hydrate‐Bearing Permafrost Sediments

Xenon Hydrate as an Analog of Methane Hydrate in Geologic Systems Out of Thermodynamic Equilibrium

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