Numerical simulation on the marine landslide due to gas hydrate dissociation

Lu, Xiaobing; Chen, X. D.; Lu, Li; Zhang, X. H.

doi:10.1007/s12665-017-6477-0

Cited by 9 publications

(5 citation statements)

References 15 publications

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“…In the residual state (Fig. 3a), water mainly exists in the form of absorbed water and isolated pockets of free water (capillary meniscus) (Lu and Likos 2004;Vanapalli et al 1996). The movement of water in this state is governed by film flow, which is such an extremely slow process (hydraulic conductivity Ks < 10 -11 m/s) (Peters 2013;Tokunaga 2009) that it is typically neglected.…”

Section: Excess Gas Methodsmentioning

confidence: 99%

“…When the pressure and/or temperature changes from the thermodynamic equilibrium state in the hydrate stability zone to the instability zone due to climate change, sea-level variation, and involvement in gas exploitation (e.g., depressurization, thermal stimulation, CH4-CO2 replacement, and inhibitor injection), the gas hydrate dissociates into water and gas (Goto et al 2016;Horozal et al 2017;Kwon et al 2008;Ruppel and Kessler, 2017;Sultan et al 2004;Wallmann et al 2018;Waite et al 2009). This dissociation will lead to degradation of the mechanical properties (e.g., stiffness, strength, dilation) of the hydrate-bearing sediment (HBS), resulting in various disasters, such as submarine landslides, differential subsidence of the seafloor, instability of the foundations of seafloor structures, destruction of the production well and the drilling installation (Brown et al 2006;Horozal et al 2017;Lu et al 2017;Jin et al 2019;Kayen et al 1991;Li and He 2011;Nixon and Grozic 2007;Scholz et al 2011;Song et al 2019a;Sultan et al 2004;Sun et al 2018;Xu and Germanovich 2006;Zander et al 2018). Therefore, it is paramount to ascertain the stability of the HBS for safe gas exploitation.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Hydrate morphology and mechanical behavior of hydrate-bearing sediments: a critical review

Hou

Huang

et al. 2022

Geomech. Geophys. Geo-energ. Geo-resour.

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and differences of the hydrate morphology in the HBS synthesized using the excess-gas and excess-water methods are highlighted. The available experimental data on the small-strain stiffness, strength, and stressstrain behavior are critically selected and grouped into two categories based on the synthesizing methods. It has been creatively discovered that most mechanical parameters (e.g., bulk modulus, shear modulus, cohesion, dilation angle) share a concave power relationship with the hydrate saturation S H for the HBS synthesized using the excess-water method. While it is a convex power relationship for the bulk modulus, shear modulus, and dilation angle, and a linear relationship for the cohesion c when the HBS is synthesized using the excess-gas method. These observations contribute to establishing the conceptual model reflecting the particle-level failure mechanism of the Abstract Natural gas hydrate is a promising energy resource in the future because of its little contamination and huge reserve. However, gas exploitation may induce large deformation and failure of the seabed due to a reduction in the stiffness and strength of the hydrate-bearing sediment (HBS). Therefore, it is essential to investigate the mechanical behavior of the HBS for safe and efficient gas exploitation. Additionally, it is widely acknowledged that the hydrate morphology inherently affects the mechanical behavior of the HBS. This paper aims to critically synthesize the information on the hydrate morphology and mechanical behavior of the HBS available in the literature to facilitate the application of the research result into engineering practice and provide guidance for future investigation. Hydrate morphology is identified firstly both in natural and synthesized HBS. The similarities

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Section: Excess Gas Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hydrate morphology and mechanical behavior of hydrate-bearing sediments: a critical review

Hou

Huang

et al. 2022

Geomech. Geophys. Geo-energ. Geo-resour.

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“…Submarine landslides are the most common and frequent geological hazards in the ocean [1,2]. Both natural and human activities, such as earthquake, gas hydrates dissociation [3,4], and hydrocarbon production [5], are able to trigger submarine landslides. As opposed to terrestrial landslides, submarine landslides normally affect a wider range of areas [6,7], not only posing a great risk to submarine pipelines and other seafloor structures [8,9] but also causing severe casualties due to tsunamis.…”

Section: Introductionmentioning

confidence: 99%

Simulation of a Submarine Landslide Using the Coupled Material Point Method

Jiajie

Zhang

Wang

et al. 2020

Mathematical Problems in Engineering

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Exploring the submarine landslide is challenging due to the invisibility nature and the complex soil-water interaction and large deformation throughout its runout process. The purpose of this paper is to investigate the ability of the coupled material point method (MPM) in modeling the soil flows under water. A sand-column collapse experiment is performed fully under water initially, with the results used to benchmark the MPM analysis. Thereafter, the whole failure process of a real submarine landslide in the South Mediterranean sea is simulated using MPM. The results show that MPM can be a reliable tool in capturing the postfailure behaviors of the submarine landslide. The failure mode of the landslide is flow-type, with an initial translational slide moving to a diffusive one eventually.

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“…If the conditions change, the hydrate releases methane gas and the physical properties of the seafloor sediment are also altered. As a result, the mechanical properties of seabed sediments are greatly reduced and the seabed is softened, causing large-scale submarine landslides, collapses, and the destruction of subsea engineering facilities [6,7,8]. Therefore, in-situ and long-term monitoring of subsidence during the exploitation of submarine gas hydrates is of great significance for the study of the formation mechanism of submarine landslides, hydrate environmental impact assessment, and early warning.…”

Section: Introductionmentioning

confidence: 99%

Experimental Research on Data Synchronous Acquisition Method of Subsidence Monitoring in Submarine Gas Hydrate Mining Area

Chen

Cao

et al. 2019

Sensors

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The data synchronous acquisition is crucial to the seafloor subsidence monitoring system for gas hydrate mining areas based on microelectromechanical sensors (MEMS). Because the independent and high-precision time reference sources on land cannot be used on the seafloor, especially in the deep sea, a relative time synchronization method based on input/output (I/O) and controller area network (CAN) bus was proposed to realize the internal time synchronization of the system. To demonstrate the feasibility of the proposed method, tests including the deformation test of the MEMS sensor array under high pressure, synchronous accuracy test, and landslide and collapse simulation tests were carried out. The synchronization method was performed once every 24 h, and the time drift was reduced to 0.38 ms from more than 30 ms, demonstrating that method can achieve consistent internal time of the system. The method does not require additional hardware devices and has adjustable accuracy.

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Numerical simulation on the marine landslide due to gas hydrate dissociation

Cited by 9 publications

References 15 publications

Hydrate morphology and mechanical behavior of hydrate-bearing sediments: a critical review

Hydrate morphology and mechanical behavior of hydrate-bearing sediments: a critical review

Simulation of a Submarine Landslide Using the Coupled Material Point Method

Experimental Research on Data Synchronous Acquisition Method of Subsidence Monitoring in Submarine Gas Hydrate Mining Area

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