Multiscale Laboratory Verification of Depressurization for Production of Sedimentary Methane Hydrates

Almenningen, Stian; Flatlandsmo, Josef; Fernø, Martin A.; Ersland, Geir

doi:10.2118/180015-pa

Cited by 37 publications

(23 citation statements)

References 6 publications

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“…This suggests that the multiple dissociation pressures needed to completely dissociate the methane gas hydrate in Figure during depressurization, where methane hydrate surrounded by water dissociated at a higher pressure compared with methane hydrate surrounded by methane gas, are due to pore water freshening and not local endothermic effects. In fact, previous methane gas hydrate depressurization experiments with distilled water show that the rate of dissociation is higher when hydrate is surrounded by gas because of increased mobility of the liberated gas (Almenningen et al, ). In addition, the observed dissociation pattern is influenced by surface roughness on the pore floor, where discrete brine droplets resided below the methane gas phase after drainage (Figure ).…”

Section: Resultsmentioning

confidence: 99%

“…Two methane gas hydrate growth patterns were observed: shell‐like growth along the gas‐water interface resulting in a porous hydrate with encapsulated methane gas in a shell of methane gas hydrate (column a, Figure ) or crystalline growth where all the free methane gas was consumed and the pore was filled with solid nonporous methane gas hydrate (column b, Figure ). The resulting hydrate configuration (porous or nonporous) was inferred from color analysis of the hydrate phase (Almenningen et al, ). The former shell‐type growth was most frequently observed, with methane gas inside the methane gas hydrate shell, presumably because of lack of water transport across the hydrate shell and/or insufficient pressure in the gas phase to maintain further growth (Almenningen et al, ; Peng et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…The water‐wet nature of grains induced a curved interface between water and gas (Figure ) and made it possible to differentiate between fluid phases. Segmented images were used to calculate two‐dimensional fluid saturations, but pixel counting does not necessarily reflect the true volumetric saturation in the pore space because multiple phases can coexist in the same location in the vertical depth of 25 μm (Almenningen et al, ). Pixel counting assumes that each pixel is saturated with only one fluid phase and is an approximation to the volumetric saturation.…”

Section: Methodsmentioning

confidence: 99%

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Salinity Effects on Pore‐Scale Methane Gas Hydrate Dissociation

et al. 2018

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Methane gas hydrate may become a significant source of methane gas in the global energy mix for the next decades. The widespread distribution of methane gas hydrate, primarily in subsea sediments on continental margins, makes the crystalline compound attractive for countries with shorelines that seek self‐sustainable energy. Fundamental understanding of pore‐level methane gas hydrate distribution and dissociation pattern in reservoirs is important to anticipate the methane production rate and overall efficiency. Specifically, the local salinity gradients occurring during methane gas hydrate dissociation, and its impact on local dissociation characteristics, must be understood as the aqueous phase in most reservoirs is saline. We experimentally evaluate the salinity effect on methane gas hydrate dissociation using high‐pressure silicon‐wafer micromodels with realistic sandstone grain characteristics. Methane gas hydrate was formed for a range of brine salinities (0–5 wt% NaCl), and we report variations in dissociation patterns during depressurization and thermal stimulation as a function of brine salinity. A strong correlation between initial methane gas hydrate distribution and dissociation characteristic, and subsequent release and mobilization of methane gas, was observed. Local water salinities affected the methane gas hydrate structure leading to distinct dissociation patterns of self‐preservation due to water freshening.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Salinity Effects on Pore‐Scale Methane Gas Hydrate Dissociation

et al. 2018

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“…The relationship between signal intensity and water saturation during hydrate growth was thus investigated, and is shown for both experiments in Figure 3. The average water saturation during hydrate growth was calculated based on the amount of consumed methane gas at a constant pressure [17]. A hydration number of 5.99 was used [18].…”

Section: Intensity Vs Water Saturationmentioning

confidence: 99%

Magnetic Resonance Imaging of Methane Hydrate Formation and Dissociation in Sandstone with Dual Water Saturation

2019

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This paper reports formation and dissociation patterns of methane hydrate in sandstone. Magnetic resonance imaging spatially resolved hydrate growth patterns and liberation of water during dissociation. A stacked core set-up using Bentheim sandstone with dual water saturation was designed to investigate the effect of initial water saturation on hydrate phase transitions. The growth of methane hydrate (P = 8.3 MPa, T = 1–3 °C) was more prominent in high water saturation regions and resulted in a heterogeneous hydrate saturation controlled by the initial water distribution. The change in transverse relaxation time constant, T2, was spatially mapped during growth and showed different response depending on the initial water saturation. T2 decreased significantly during growth in high water saturation regions and remained unchanged during growth in low water saturation regions. Pressure depletion from one end of the core induced a hydrate dissociation front starting at the depletion side and moving through the core as production continued. The final saturation of water after hydrate dissociation was more uniform than the initial water saturation, demonstrating the significant redistribution of water that will take place during methane gas production from a hydrate reservoir.

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“…These deposits remain untouched and hold a reserve estimated to be twice the amount of known fossil fuels available [3][4][5]. To produce methane from a gas hydrate reservoir, several techniques have been suggested, including depressurization [6], thermal stimulation [7] and chemical inhibitor injection [8]. In comparison, depressurization is considered as the most cost-effective method to be commercially applied.…”

Section: Introductionmentioning

confidence: 99%

Enhanced CH4-CO2 Hydrate Swapping in the Presence of Low Dosage Methanol

et al. 2020

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CO2-rich gas injection into natural gas hydrate reservoirs is proposed as a carbon-neutral, novel technique to store CO2 while simultaneously producing CH4 gas from methane hydrate deposits without disturbing geological settings. This method is limited by the mass transport barrier created by hydrate film formation at the liquid–gas interface. The very low gas diffusivity through hydrate film formed at this interface causes low CO2 availability at the gas–hydrate interface, thus lowering the recovery and replacement efficiency during CH4-CO2 exchange. In a first-of-its-kind study, we have demonstrate the successful application of low dosage methanol to enhance gas storage and recovery and compare it with water and other surface-active kinetic promoters including SDS and L-methionine. Our study shows 40–80% CH4 recovery, 83–93% CO2 storage and 3–10% CH4-CO2 replacement efficiency in the presence of 5 wt% methanol, and further improvement in the swapping process due to a change in temperature from 1–4 °C is observed. We also discuss the influence of initial water saturation (30–66%), hydrate morphology (grain-coating and pore-filling) and hydrate surface area on the CH4-CO2 hydrate swapping. Very distinctive behavior in methane recovery caused by initial water saturation (above and below Swi = 0.35) and hydrate morphology is also discussed. Improved CO2 storage and methane recovery in the presence of methanol is attributed to its dual role as anti-agglomerate and thermodynamic driving force enhancer between CH4-CO2 hydrate phase boundaries when methanol is used at a low concentration (5 wt%). The findings of this study can be useful in exploring the usage of low dosage, bio-friendly, anti-agglomerate and hydrate inhibition compounds in improving CH4 recovery and storing CO2 in hydrate reservoirs without disturbing geological formation. To the best of the authors’ knowledge, this is the first experimental study to explore the novel application of an anti-agglomerate and hydrate inhibitor in low dosage to address the CO2 hydrate mass transfer barrier created at the gas–liquid interface to enhance CH4-CO2 hydrate exchange. Our study also highlights the importance of prior information about methane hydrate reservoirs, such as residual water saturation, degree of hydrate saturation and hydrate morphology, before applying the CH4-CO2 hydrate swapping technique.

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Multiscale Laboratory Verification of Depressurization for Production of Sedimentary Methane Hydrates

Cited by 37 publications

References 6 publications

Salinity Effects on Pore‐Scale Methane Gas Hydrate Dissociation

Salinity Effects on Pore‐Scale Methane Gas Hydrate Dissociation

Magnetic Resonance Imaging of Methane Hydrate Formation and Dissociation in Sandstone with Dual Water Saturation

Enhanced CH4-CO2 Hydrate Swapping in the Presence of Low Dosage Methanol

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