2020
DOI: 10.3390/geosciences10120504
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Factors Affecting the Formation and Evolution of Permafrost and Stability Zone of Gas Hydrates: Case Study of the Laptev Sea

Abstract: The key factors controlling the formation and dynamics of relicpermafrost and the conditions for the stability of associated gas hydrates have been investigated using numerical modeling in this work. A comparison was made between two scenarios that differed in the length of freezing periods and corresponding temperature shifts to assess the impact on the evolution of the permafrost–hydrate system and to predict its distribution and geometry. The simulation setup included the specific heat of gas hydrate format… Show more

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Cited by 17 publications
(12 citation statements)
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“…In Equation (A6), c pr is the specific heat capacity of the immobile components, including the sediment matrix, ice and hydrate, which is modified by introducing the ice component to the formula and taking the latent heat of ice formation, L [11], into account:…”
Section: Appendix A2 Governing Equations Describing Water-ice Thermal...mentioning
confidence: 99%
See 1 more Smart Citation
“…In Equation (A6), c pr is the specific heat capacity of the immobile components, including the sediment matrix, ice and hydrate, which is modified by introducing the ice component to the formula and taking the latent heat of ice formation, L [11], into account:…”
Section: Appendix A2 Governing Equations Describing Water-ice Thermal...mentioning
confidence: 99%
“…(1) the mean annual temperature at the base of the active layer, (2) the thermal conductivity of sediments and (3) the basal heat flow [9]. During the recent glacial-interglacial history and regressive/transgressive marine cycles, permafrost forms or degrades, while the latent heat of the water-ice phase changes is consumed or released over considerable amounts of time [10,11]. In general, permafrost evolution is accompanied by the formation of permafrost-associated GHs, including the shallow pan-Arctic continental shelves and coastal plains [12,13] and the Qinghai-Tibet Plateau [14].…”
Section: Introduction 1arctic Permafrost-associated Gas Hydratesmentioning
confidence: 99%
“…The prediction of the occurrence of HSZs is mainly controlled by factors such as the mean annual ground surface temperature, the thickness of the frozen soil, the geothermal gradient, the formation pressure, the groundwater salinity, and the composition of guest molecules. , These factors determine whether the formation temperature gradient curve can theoretically intersect with the hydrate-phase equilibrium curve to create an enclosed area between these two, which represents the formation conditions and depth interval occurrences of the HZS. Based on what has been presented so far, this paper discusses the factors that have a significant and direct impact on the presence and other characteristics of HSZs, such as the thickness of the frozen soil, the geothermal gradient, the formation pressure, and the composition of guest molecules.…”
Section: Discussionmentioning
confidence: 99%
“…Three other papers [10][11][12] deal with natural gas seeps in the Arctic shelf. Chernykh et al [10] overview the existing approaches to echo sounding of methane bubble fluxes from the sea bottom into the water and suggest a new technique for quantitative evaluation of methane seepage from the cross section area of a back scattering CH4 bubble plume.…”
mentioning
confidence: 99%
“…Gas seeps detected in the East Siberian Arctic shelf may guide to zones of permafrost degradation and related destabilization of gas hydrates. Matveeva et al [11] simulated various effects on the evolution of permafrost and on the zone of gas hydrate stability in the Laptev Sea, for two scenarios. The scenarios, with different durations of frost season and the respective temperature shifts, were compared to estimate their influence on the permafrost-hydrate system and to predict the pattern of the latter.…”
mentioning
confidence: 99%