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Apr 15, 2021;11 (24): 14334-14346.

Insights into the climate-driven evolution of gas hydrate-bearing permafrost sediments: implications for prediction of environmental impacts and security of energy in cold regions.

Mehrdad Vasheghani Farahani, Aliakbar Hassanpouryouzband, Jinhai Yang, Bahman Tohidi
Author Information
  1. Mehrdad Vasheghani Farahani: Hydrates, Flow Assurance & Phase Equilibria Research Group, Institute of GeoEnergy Engineering, Heriot-Watt University Edinburgh EH14 4AS UK petjy@hw.ac.uk. ORCID
  2. Aliakbar Hassanpouryouzband: Hydrates, Flow Assurance & Phase Equilibria Research Group, Institute of GeoEnergy Engineering, Heriot-Watt University Edinburgh EH14 4AS UK petjy@hw.ac.uk. ORCID
  3. Jinhai Yang: Hydrates, Flow Assurance & Phase Equilibria Research Group, Institute of GeoEnergy Engineering, Heriot-Watt University Edinburgh EH14 4AS UK petjy@hw.ac.uk. ORCID
  4. Bahman Tohidi: Hydrates, Flow Assurance & Phase Equilibria Research Group, Institute of GeoEnergy Engineering, Heriot-Watt University Edinburgh EH14 4AS UK petjy@hw.ac.uk.
PMID: 35423992 DOI: 10.1039/d1ra01518d

Abstract

The present study investigates the evolution of gas hydrate-bearing permafrost sediments against the environmental temperature change. The elastic wave velocities and effective thermal conductivity (ETC) of simulated gas hydrate-bearing sediment samples were measured at a typical range of temperature in permafrost and wide range of hydrate saturation. The experimental results reveal the influence of several complex and interdependent pore-scale factors on the elastic wave velocities and ETC. It was observed that the geophysical and geothermal properties of the system are essentially governed by the thermal state, saturation and more significantly, pore-scale distribution of the co-existing phases. In particular, unfrozen water content substantially controls the heat transfer at sub-zero temperatures close to the freezing point. A conceptual pore-scale model was also proposed to describe the pore-scale distribution of each phase in a typical gas hydrate-bearing permafrost sediment. This study underpins necessity of distinguishing ice from gas hydrates in frozen sediments, and its outcome is essential to be considered not only for development of large-scale permafrost monitoring systems, bus also accurate quantification of natural gas hydrate as a potential sustainable energy resource in cold regions.

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Journal Article
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