Gas hydrate characterization in sediments via x-ray microcomputed tomography

Abbasi, Ghazanfer Raza; Arif, Muhammad; Isah, Abubakar; Ali, Muhammad; Mahmoud, Mohamed; Hoteit, Hussein; Keshavarz, Alireza; Iglauer, Stefan

doi:10.1016/j.earscirev.2022.104233

Cited by 16 publications

(11 citation statements)

References 131 publications

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“…References , , and collectively highlight the necessity of understanding the complex interaction between sediment properties, hydrate morphology, and flow dynamics within pore-scale environments for informed decision-making regarding CO 2 hydrate storage strategies.…”

Section: Influence Of Sediment Properties On Co2 Hydrate Storagementioning

confidence: 99%

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

Kasala,

Fang,

Wang

et al. 2024

Energy Fuels

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Exploring various strategies for CO 2 hydrate storage in subseafloor saline sediments reveals a promising yet challenging path toward mitigating anthropogenic CO 2 emissions and advancing clean energy development. Research has revealed the efficacy of sediment-specific modifications, including the use of inorganic emulsifiers, L-leucine (an amino acid), and nanoparticle coatings, in enhancing CO 2 hydrate formation stability and storage capacity. These modifications aid in overcoming the challenges posed by the harsh environmental conditions of salinity and sediment heterogeneity, providing increased stability, enhanced CO 2 adsorption efficiency, and reduced induction time. Furthermore, advancements in nanomaterials have introduced nanostructured encapsulation systems capable of confining and stabilizing CO 2 within a solid matrix under fluctuating pressure, temperature, and salinity conditions. Incorporating nanoparticles into polymers and surfactants yields a nanofluid that exhibits increased stability, improved wettability, interfacial tension (IFT) reduction, and elevated CO 2 hydrate storage efficiency, with the synergistic effects of these components playing a critical role. Moreover, innovative thermal and pressure manipulation strategies, alongside the integration of kinetic promoters, have shown significant potential in optimizing CO 2 hydrate formation kinetics and enhancing longterm stability. These strategies involve novel electrical heating systems, pressure management techniques, and chemical additives that collectively contribute to increased hydrate formation rates and gas storage capacities. Despite these promising developments, the field faces several challenges, including optimizing encapsulation materials to match geological characteristics, the long-term stability of CO 2 hydrates under extreme conditions, and scaling laboratory experiments to field applications. Addressing these issues necessitates a multifaceted approach, incorporating empirical data and theoretical insights to design, screen, and formulate effective CO 2 hydrate storage solutions in subseafloor saline sediments.

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Section: Influence Of Sediment Properties On Co2 Hydrate Storagementioning

confidence: 99%

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

Kasala,

Fang,

Wang

et al. 2024

Energy Fuels

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“…In addition, there are some unconventional techniques, such as lined/unlined hard rock caverns, abandoned coal mines, and refrigerated mined caverns . Gas hydrates can also be an effective medium for storing hydrogen. , Hydrogen storage has also been studied in formic acid, liquid organic hydride, ammonia, ammonia borane, and so on. However, for large-scale hydrogen storage, underground geological structures are preferred.…”

Section: Introductionmentioning

confidence: 99%

“…19 Gas hydrates can also be an effective medium for storing hydrogen. 20,21 Hydrogen storage has also been studied in formic acid, 22 liquid organic hydride, 23 ammonia, 24 ammonia borane, 25 and so on. However, for largescale hydrogen storage, underground geological structures are preferred.…”

Section: Introductionmentioning

confidence: 99%

A Mini-Review on Underground Hydrogen Storage: Production to Field Studies

et al. 2023

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Hydrogen has become increasingly popular as one of the alternative fuels to reduce greenhouse gas emissions. Storing hydrogen in geological structures is a technology that shows great potential in storing large amounts of hydrogen efficiently. However, this technology is relatively new and requires a clear understanding. Therefore, a quick review of underground hydrogen storage is needed to understand its fundamental concepts. This review article presents important components relevant to underground hydrogen storage. First, some currently available hydrogen production methods are discussed followed by hydrogen storage methods. Both small-scale and large-scale hydrogen storage methods are presented. Next, some important factors (fluid properties, rock properties, solid−fluid interactions, and chemical interactions) influencing underground hydrogen storage are summarized. This is followed by presenting various interesting field studies for underground hydrogen storage. Lastly, some challenges and future outlooks pertinent to underground hydrogen storage are reviewed. This article will serve as a useful resource that provides a quick overview of underground hydrogen storage for both researchers and industrialists.

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“…5 The formation, extraction, and reserve assessment of NGH has been the research focus in recent years. 6 Unlike conventional oil and gas resource development, the interaction among hydrate, sediments, and pore fluids not only affects further decomposition and production of NGH but also induces the stability of hydrate reservoir and sand production problems during the production of NGH. 7−9 The process of NGH exploitation is achieved by disrupting its temperature and pressure equilibrium conditions, and the main exploitation methods include the thermal stimulation method, depressurization method, injection of inhibitors method, and carbon dioxide replacement method.…”

Section: Introductionmentioning

confidence: 99%

“…The formation, extraction, and reserve assessment of NGH has been the research focus in recent years . Unlike conventional oil and gas resource development, the interaction among hydrate, sediments, and pore fluids not only affects further decomposition and production of NGH but also induces the stability of hydrate reservoir and sand production problems during the production of NGH. − The process of NGH exploitation is achieved by disrupting its temperature and pressure equilibrium conditions, and the main exploitation methods include the thermal stimulation method, depressurization method, injection of inhibitors method, and carbon dioxide replacement method. − Some scholars have found that the continuous decomposition of hydrate makes pore water pressure rise and effective stress decrease in the reservoir during the mining process, resulting in the reduction of hydrate reservoir strength. , However, it also has been found that the reduction of pore pressure and the increase of effective stress are observed during the depressurization process, which leads to the volume deformation of the sediments .…”

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Gas Hydrate-Bearing Sediments Influenced by Multiple Factors: A Comprehensive Review of Triaxial Tests

Zeng,

Kong,

Zhao

et al. 2023

Energy Fuels

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Natural gas hydrate (NGH) has the characteristics of low pollution and large reserves, which is considered as a very promising energy source. The extraction of NGH would cause the strength and stiffness reduced in hydrate-bearing sediment (HBS) reservoirs, which could lead to geological disasters. The mechanical properties of HBS have been studied by a large number of scholars, but it has not been sorted out and summarized for HBS under the influence of multiple factors. In this paper, the hydrate types, synthesis methods, and test conditions are summarized. The effects of hydrate saturation, loading rate, temperature, pore pressure, confining pressure, fine content, and clay content on mechanical properties and deformation behavior of HBS are outlined. The microstructure of the synthesis, decomposition, and shear processes of HBS specimens is also analyzed based on the CT triaxial shear test system, and the microscopic mechanism of HBS specimens in the shearing process is summarized. Finally, the shortcomings of current research on the mechanical properties of HBS are discussed, and provided corresponding suggestions to promote the development of the mechanical properties of HBS.

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Gas hydrate characterization in sediments via x-ray microcomputed tomography

Cited by 16 publications

References 131 publications

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

A Mini-Review on Underground Hydrogen Storage: Production to Field Studies

Mechanical Properties of Gas Hydrate-Bearing Sediments Influenced by Multiple Factors: A Comprehensive Review of Triaxial Tests

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Gas hydrate characterization in sediments via x-ray microcomputed tomography

Cited by 16 publications

References 131 publications

Comprehensive Review and Perspectives of CO2 Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

Comprehensive Review and Perspectives of CO2 Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

A Mini-Review on Underground Hydrogen Storage: Production to Field Studies

Mechanical Properties of Gas Hydrate-Bearing Sediments Influenced by Multiple Factors: A Comprehensive Review of Triaxial Tests

Contact Info

Product

Resources

About

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies

Comprehensive Review and Perspectives of CO₂ Hydrate Storage in Subseafloor Saline Sediments: Formation, Stability, and Optimization Strategies