Your search keyword '"V.V. Olenchenko"' showing total 2 results

1. Detecting and Mapping Gas Emission Craters on the Yamal and Gydan Peninsulas, Western Siberia

Author

Susan M. Natali, V.V. Olenchenko, Tiffany Windholz, Alexey Faguet, Zhiqiang Yang, Gabriel Duran, Scott Zolkos, and Greg Fiske

Subjects

010504 meteorology & atmospheric sciences, thermokarst, cryovolcanism, landscape change, 010502 geochemistry & geophysics, Permafrost, 01 natural sciences, Methane, Thermokarst, Latitude, chemistry.chemical_compound, remote sensing, Impact crater, Peninsula, GEC, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Global warming, lcsh:QE1-996.5, Elevation, ArcticDEM, lcsh:Geology, chemistry, General Earth and Planetary Sciences, Physical geography, methane crater, Google Earth Engine, Landsat, Geology, permafrost

Abstract

Rapid climate warming at northern high latitudes is driving geomorphic changes across the permafrost zone. In the Yamal and Gydan peninsulas in western Siberia, subterranean accumulation of methane beneath or within ice-rich permafrost can create mounds at the land surface. Once over-pressurized by methane, these mounds can explode and eject frozen ground, forming a gas emission crater (GEC). While GECs pose a hazard to human populations and infrastructure, only a small number have been identified in the Yamal and Gydan peninsulas, where the regional distribution and frequency of GECs and other types of land surface change are relatively unconstrained. To understand the distribution of landscape change within 327,000 km2 of the Yamal-Gydan region, we developed a semi-automated multivariate change detection algorithm using satellite-derived surface reflectance, elevation, and water extent in the Google Earth Engine cloud computing platform. We found that 5% of the landscape changed from 1984 to 2017. The algorithm detected all seven GECs reported in the scientific literature and three new GEC-like features, and further revealed that retrogressive thaw slumps were more abundant than GECs. Our methodology can be refined to detect and better understand diverse types of land surface change and potentially mitigate risks across the northern permafrost zone.

Published

2021

2. Heat and salt flow in subsea permafrost modeled with CryoGRID2

Author

V.V. Olenchenko, Guido Grosse, Paul Overduin, Alexey Faguet, Sebastian Westermann, Mikhail N. Grigoriev, and Michael Angelopoulos

Subjects

Informatics, Lena Delta, 010504 meteorology & atmospheric sciences, Permafrost, Permafrost, Cryosphere, and High-Latitude Processes, Biogeosciences, 01 natural sciences, Thermokarst, Ice Mechanics and Air/Sea/Ice Exchange Processes, Bykovsky Peninsula, Sea ice, ddc:550, Instruments and Techniques, 14. Life underwater, subsea permafrost, Geomorphology, Research Articles, Seabed, 0105 earth and related environmental sciences, Earth-Surface Processes, geography, geography.geographical_feature_category, salt diffusion, Sea Ice, Modeling, CryoGRID, Physical Modeling, Coastal erosion, Geophysics, subsea permafrost, salt diffusion, CryoGRID, Lena Delta, Bykovsky Peninsula, electrical resistivity, Arctic, 13. Climate action, Seawater, Submarine pipeline, Other, Institut für Geowissenschaften, Cryosphere, Natural Hazards, Geology, Oceanography: Physical, Research Article, electrical resistivity, Subsea

Abstract

Thawing of subsea permafrost can impact offshore infrastructure, affect coastal erosion, and release permafrost organic matter. Thawing is usually modeled as the result of heat transfer, although salt diffusion may play an important role in marine settings. To better quantify nearshore subsea permafrost thawing, we applied the CryoGRID2 heat diffusion model and coupled it to a salt diffusion model. We simulated coastline retreat and subsea permafrost evolution as it develops through successive stages of a thawing sequence at the Bykovsky Peninsula, Siberia. Sensitivity analyses for seawater salinity were performed to compare the results for the Bykovsky Peninsula with those of typical Arctic seawater. For the Bykovsky Peninsula, the modeled ice‐bearing permafrost table (IBPT) for ice‐rich sand and an erosion rate of 0.25 m/year was 16.7 m below the seabed 350 m offshore. The model outputs were compared to the IBPT depth estimated from coastline retreat and electrical resistivity surveys perpendicular to and crossing the shoreline of the Bykovsky Peninsula. The interpreted geoelectric data suggest that the IBPT dipped to 15–20 m below the seabed at 350 m offshore. Both results suggest that cold saline water forms beneath grounded ice and floating sea ice in shallow water, causing cryotic benthic temperatures. The freezing point depression produced by salt diffusion can delay or prevent ice formation in the sediment and enhance the IBPT degradation rate. Therefore, salt diffusion may facilitate the release of greenhouse gasses to the atmosphere and considerably affect the design of offshore and coastal infrastructure in subsea permafrost areas., Key Points The thawing of ice‐bearing subsea permafrost was modeled by coupling heat and salt diffusionThe boundary conditions reflect sea ice dynamics during the transition from terrestrial to marine permafrostThe modeled ice‐bearing permafrost depths were validated with geoelectric surveys

Published

2019