An experimental investigation on methane hydrate morphologies and pore habits in sandy sediment using synchrotron X-ray computed tomography

Le, Thi-Xiu; Bornert, Michel; Aimedieu, Patrick; Chabot, Baptiste; King, Andrew; Tang, Anh-Minh

doi:10.1016/j.marpetgeo.2020.104646

Cited by 30 publications

(34 citation statements)

References 42 publications

(63 reference statements)

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“…(2016) . This is because although water can migrate among the sand particles ( Le et al., 2020 ; Nikitin et al., 2020 ), it is still physically impossible to float at the pore space in a gas excess environment. Figure 1 E shows the hydrate spatial distribution influence on the radii distribution of the pore space.…”

Section: Resultsmentioning

confidence: 99%

“…Xenon gas is used to generate xenon hydrate (XeH) instead of methane gas to enhance the phase contrast in the CT images. Moreover, it must be noted that the physical characteristics between the XeH and NGH are also quite close ( Chaouachi et al., 2015 ; Ning et al., 2012 ), as are the pore-scale occurrences between XeH and NGH following the similar formation procedure ( Lei et al., 2019 ; Le et al., 2020 ). Furthermore, the substitutability of XeH for NGH for some pore-habit evolution studies has been widely accepted ( Chaouachi et al., 2015 ; Yang et al., 2016 ).…”

Section: Methodsmentioning

confidence: 99%

“…Nevertheless, the vast majority of studies did not consider the hydrate cementation spatial distribution influence on the mechanical behavior of hydrate-bearing sediments due to the lack of an effective nondestructive technique. Moreover, in nature, the hydrate cementation pore habit was reported to be heterogeneous affected by the effective stress, pore-size-dependent capillary pressure, and hydrocarbon accumulation history, which has been assessed directly by X-ray computed tomography (CT) (Lei et al, 2019;Le et al, 2020) or magnetic resonance imaging (MRI) (Ji et al, 2020;Song et al, 2015;Zhang et al, 2020b) and indirectly by comparing the measured seismic velocities and those calculated via elasticity models (Dvorkin et al, 2000). Luo et al (2015) studied the effect of a heterogeneous distribution of the hydrates on the wave velocity of the sediment and found that the compressional wave velocity increases with the hydrate saturation, while the heterogeneous distribution of the hydrates can have a remarkable influence on the results, especially in the low-saturation condition.…”

Section: Introductionmentioning

confidence: 99%

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Mechanical behaviors of hydrate-bearing sediment with different cementation spatial distributions at microscales

Sun

et al. 2021

iScience

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mechanical behaviors of hydrate-bearing sediment with different cementation spatial distributions at microscales

Sun

et al. 2021

iScience

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“…The proposed growth mechanism would lead to hydrate growth stiffening up particle contacts from the outset, which is supported by the rapid increase in G max as hydrate formation proceeds (Figure 4) as observed in our tests as well as others (Clayton et al, 2005;Sultaniya et al, 2018) where the excess-gas method is used. using X-ray CT imaging suggest that in a gas-saturated environment hydrate growth occurs on the mineral surfaces and grows into the pore space, while Le et al (2020) showed that both mineral coating hydrate and hydrate at grain contacts can exist locally. Given the small sampling size used in CT studies, it is highly probable that at the specimen scale extensive grain contacts "cemented" by hydrate exists that leads to the large stiffening effect.…”

Section: Factors Affecting G Max During Hydrate Formationmentioning

confidence: 99%

The Change in Geomechanical Properties of Gas Saturated Methane Hydrate‐Bearing Sand Resulting From Water Saturation

2021

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Laboratory tests were carried out on gas‐saturated hydrate‐bearing sand (HBS) specimens that were subsequently water saturated to determine the influence of water saturation on their small‐strain (stiffness) and large‐strain (strength) behavior. Hydrate formed using the “excess gas” method led to significant increases in stiffness and strength of the sand. The magnitude increase in stiffness was largest for the lowest hydrate saturation tests and was sensitive to the distribution of hydrate within the sand. In contrast, increases in strength were directly related to increases in hydrate saturation, and to a lesser extent, on the applied confining stresses. Subsequent water saturation of these gas‐saturated HBS (achieved by flushing up to three times the pore volume of water through the HBS specimen) led to ∼90% and ∼70% reduction in stiffness and strength, respectively, along with a 37% reduction in hydrate volume (initial hydrate pore saturation ∼21.5%). Specimens with higher initial hydrate saturations (∼48%) saw slightly smaller reductions in stiffness and strength associated with ∼17% reduction in hydrate saturation. Changes in behavior appear to be related to the reduction of “cementing” hydrate at particle contacts through dissociation/dissolution of the hydrate, with remaining hydrate being more “pore filling.” Processes that may induce fluid flow in a natural gas‐saturated HBS, such as during the depressurization of the HBS reservoir during hydrate production, may lead to changes in hydrate morphology and affect the geomechanical properties of the HBS even when the HBS are still under hydrate stability conditions.

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“…Even though it is helpful to build geophysical and reservoir models, this categorization of hydrate distribution within the pore space lacks direct experimental confirmation. The very scarce high-resolution imaging studies by means of synchrotron X-ray computed tomography (XRCT) in fact point to more complex features of gas hydrate formation and growth in sediment pores [16][17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Combining Optical Microscopy and X-ray Computed Tomography Reveals Novel Morphologies and Growth Processes of Methane Hydrate in Sand Pores

Bornert

Brown

et al. 2021

Energies

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Understanding the mechanisms involved in the formation and growth of methane hydrate in marine sandy sediments is crucial for investigating the thermo-hydro-mechanical behavior of gas hydrate marine sediments. In this study, high-resolution optical microscopy and synchrotron X-ray computed tomography were used together to observe methane hydrate growing under excess gas conditions in a coarse sandy sediment. The high spatial and complementary temporal resolutions of these techniques allow growth processes and accompanying redistribution of water or brine to be observed over spatial scales down to the micrometre—i.e., well below pore size—and temporal scales below 1 s. Gas hydrate morphological and growth features that cannot be identified by X-ray computed tomography alone, such as hollow filaments, were revealed. These filaments sprouted from hydrate crusts at water–gas interfaces as water was being transported from their interior to their tips in the gas (methane), which extend in the µm/s range. Haines jumps are visualized when the growing hydrate crust hits a water pool, such as capillary bridges between grains or liquid droplets sitting on the substrate—a capillary-driven mechanism that has some analogy with cryogenic suction in water-bearing freezing soils. These features cannot be accounted for by the hydrate pore habit models proposed about two decades ago, which, in the absence of any observation at pore scale, were indeed useful for constructing mechanical and petrophysical models of gas hydrate-bearing sediments.

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An experimental investigation on methane hydrate morphologies and pore habits in sandy sediment using synchrotron X-ray computed tomography

Cited by 30 publications

References 42 publications

Mechanical behaviors of hydrate-bearing sediment with different cementation spatial distributions at microscales

Mechanical behaviors of hydrate-bearing sediment with different cementation spatial distributions at microscales

The Change in Geomechanical Properties of Gas Saturated Methane Hydrate‐Bearing Sand Resulting From Water Saturation

Combining Optical Microscopy and X-ray Computed Tomography Reveals Novel Morphologies and Growth Processes of Methane Hydrate in Sand Pores

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