Development of a coupled geophysical-geothermal scheme for quantification of hydrates in gas hydrate-bearing permafrost sediments

Quantification of hydrates in permafrost sediments using conventional seismic techniques has always been a major challenge in the study of the climate-driven evolution of gas hydrate-bearing permafrost sediments due to almost identical acoustic properties of hydrates and ice. In this article, a coup...

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Published in:Physical chemistry chemical physics : PCCP 2021-11, Vol.23 (42), p.24249-24264
Main Authors: Vasheghani Farahani, Mehrdad, Hassanpouryouzband, Aliakbar, Yang, Jinhai, Tohidi, Bahman
Format: Article
Language:English
Subjects:
Acoustic properties
Elastic waves
Gas hydrates
Geophysics
Methane hydrates
Permafrost
Saturation
Scale models
Sediments
Thermal conductivity
Wave velocity
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Summary:Quantification of hydrates in permafrost sediments using conventional seismic techniques has always been a major challenge in the study of the climate-driven evolution of gas hydrate-bearing permafrost sediments due to almost identical acoustic properties of hydrates and ice. In this article, a coupled geophysical-geothermal scheme is developed, for the first time, to predict hydrate saturation in gas hydrate-bearing permafrost sediments by utilising their geophysical and geothermal responses. The scheme includes a geophysical part which interprets the measured elastic wave velocities using a rock-physics model, coupled with a geothermal part, interpreting the measured effective thermal conductivity (ETC) using a new pore-scale model. By conducting a series of sensitivity analyses, it is shown that the ETC model is able to incorporate the effect of the hydrate pore-scale habit and hydrate/ice-forced heave as well as the effect of unfrozen water saturation under frozen conditions. Given that the geophysical and geothermal responses depend on the overburden pressure, the elastic wave velocities and ETC of methane hydrate-bearing permafrost sediment samples were measured at different effective overburden pressures and the results were provided. These experimental data together with the results of our recent study on the geophysical and geothermal responses of gas hydrate-bearing permafrost sediment samples at different hydrate saturations are used to validate the performance of the coupled scheme. By comparing the predicted saturations with those obtained experimentally, it is shown that the coupled scheme is able to quantify the saturation of the co-existing phases with an acceptable accuracy in a wide range of hydrate saturations and at different overburden pressures. In this article, a coupled geophysical-geothermal scheme has been developed to predict hydrates saturation in gas hydrate-bearing permafrost sediments via utilising their geophysical and geothermal responses.
ISSN:1463-9076
1463-9084
DOI:10.1039/d1cp03086h