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Maximum recoverable gas from hydrate bearing sediments by depressurization

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  • Terzariol, M.
  • Goldsztein, G.
  • Santamarina, J.C.

Abstract

The estimation of gas production rates from hydrate bearing sediments requires complex numerical simulations. This manuscript presents a set of simple and robust analytical solutions to estimate the maximum depressurization-driven recoverable gas. These limiting-equilibrium solutions are established when the dissociation front reaches steady state conditions and ceases to expand further. Analytical solutions show the relevance of (1) relative permeabilities between the hydrate free sediment, the hydrate bearing sediment, and the aquitard layers, and (2) the extent of depressurization in terms of the fluid pressures at the well, at the phase boundary, and in the far field. Close form solutions for the size of the produced zone allow for expeditious financial analyses; results highlight the need for innovative production strategies in order to make hydrate accumulations an economically-viable energy resource. Horizontal directional drilling and multi-wellpoint seafloor dewatering installations may lead to advantageous production strategies in shallow seafloor reservoirs.

Suggested Citation

  • Terzariol, M. & Goldsztein, G. & Santamarina, J.C., 2017. "Maximum recoverable gas from hydrate bearing sediments by depressurization," Energy, Elsevier, vol. 141(C), pages 1622-1628.
    • Handle: RePEc:eee:energy:v:141:y:2017:i:c:p:1622-1628
    DOI: 10.1016/j.energy.2017.11.076
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    Cited by:

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    7. Xie, Yan & Cheng, Liwei & Feng, Jingchun & Zheng, Tao & Zhu, Yujie & Zeng, Xinyang & Sun, Changyu & Chen, Guangjin, 2024. "Kinetics behaviors of CH4 hydrate formation in porous sediments: Non-unidirectional influence of sediment particle size on hydrate formation," Energy, Elsevier, vol. 289(C).
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    12. Yu, Lu & Zhang, Liang & Zhang, Rui & Ren, Shaoran, 2018. "Assessment of natural gas production from hydrate-bearing sediments with unconsolidated argillaceous siltstones via a controlled sandout method," Energy, Elsevier, vol. 160(C), pages 654-667.
    13. Yang, Lei & Ai, Li & Xue, Kaihua & Ling, Zheng & Li, Yanghui, 2018. "Analyzing the effects of inhomogeneity on the permeability of porous media containing methane hydrates through pore network models combined with CT observation," Energy, Elsevier, vol. 163(C), pages 27-37.
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    15. Lin, Decai & Lu, Jingsheng & Liu, Jia & Liang, Deqing & Li, Dongliang & Jin, Guangrong & Xia, Zhiming & Li, Xiaosen, 2023. "Numerical study on natural gas hydrate production by hot water injection combined with depressurization," Energy, Elsevier, vol. 282(C).
    16. Dong, Lin & Wu, Nengyou & Leonenko, Yuri & Wan, Yizhao & Zhang, Yajuan & Li, Yanlong, 2024. "Numerical analysis on hydrate production performance with multi-well systems: Synergistic effect of adjacent wells and implications on field exploitation," Energy, Elsevier, vol. 290(C).
    17. Lu, Nu & Hou, Jian & Liu, Yongge & Barrufet, Maria A. & Bai, Yajie & Ji, Yunkai & Zhao, Ermeng & Chen, Weiqing & Zhou, Kang, 2019. "Revised inflow performance relationship for productivity prediction and energy evaluation based on stage characteristics of Class III methane hydrate deposits," Energy, Elsevier, vol. 189(C).
    18. Terzariol, M. & Santamarina, J.C., 2021. "Multi-well strategy for gas production by depressurization from methane hydrate-bearing sediments," Energy, Elsevier, vol. 220(C).
    19. Hou, Jian & Zhao, Ermeng & Liu, Yongge & Ji, Yunkai & Lu, Nu & Liu, Yueliang & Li, Huazhou Andy & Bai, Yajie, 2019. "Pressure-transient behavior in class III hydrate reservoirs," Energy, Elsevier, vol. 170(C), pages 391-402.

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