Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula

The net of dry valleys, gullies and shallow hollows is typical for the East European Plain. Dense vegetation usually covers their bottoms and slopes, so the modern erosion there is negligible in the pristine conditions. This erosion landscape formed in periglacial conditions during the terminations...

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Published in:GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY
Main Authors: Alexey Sidorchuk Yu., Tatiana Matveeva A.
Other Authors: This study was carried out with support of the Russian Science Foundation project 18-05-60147 “Extreme hydro-meteorological phenomena in the Kara Sea and the Arctic coast”
Format: Article in Journal/Newspaper
Language:English
Published: Russian Geographical Society 2020
Subjects:
The Yamal Peninsula;active gullies;East European Plain;periglacial erosion;gully erosion and thermoerosion modelling;estimates of past surface runof
Arctic
Yamal Peninsula
Tazovsky
Antarctic Science
Permafrost and Periglacial Processes
Polar Research
Online Access:https://ges.rgo.ru/jour/article/view/1043
https://doi.org/10.24057/2071-9388-2019-01
id ftjges:oai:oai.gesj.elpub.ru:article/1043
record_format openpolar
institution Open Polar
collection Geography, Environment, Sustainability (E-Journal)
op_collection_id ftjges
language English
topic The Yamal Peninsula;active gullies;East European Plain;periglacial erosion;gully erosion and thermoerosion modelling;estimates of past surface runof
spellingShingle The Yamal Peninsula;active gullies;East European Plain;periglacial erosion;gully erosion and thermoerosion modelling;estimates of past surface runof
Alexey Sidorchuk Yu.
Tatiana Matveeva A.
Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
topic_facet The Yamal Peninsula;active gullies;East European Plain;periglacial erosion;gully erosion and thermoerosion modelling;estimates of past surface runof
description The net of dry valleys, gullies and shallow hollows is typical for the East European Plain. Dense vegetation usually covers their bottoms and slopes, so the modern erosion there is negligible in the pristine conditions. This erosion landscape formed in periglacial conditions during the terminations of the last two glaciations. The same kind of the erosion landscape is typical for the Arctic regions, especially for the Yamal, Gydan, and Tazovsky peninsulas. The size and the density of such valleys and gullies are quite similar to those existing on the East European Plain, but these erosion features are active there, especially in the conditions of natural or anthropogenic deterioration of the vegetation cover. As the density of dry valley network is an indicator of hydrological conditions in the river basin, the landscapes of the Arctic regions can be used as the modern analogs of the territories with the past periglacial erosion.The recent hydrological characteristics of the west-central Yamal Peninsula were used to estimate the parameters of erosion network at the Khoper River basin, formed in periglacial conditions. For these purposes gully erosion and thermoerosion model GULTEM was verified and calibrated based on the observation of the modern processes on the Yamal Peninsula. The meteorological characteristics were taken from ERA-Interim Reanalysis grid. To calculate the flow characteristics a synthetic hydrological model was used. These verified and calibrated models were used to find the most suitable characteristics of climate and vegetation cover, which can explain the structure and density of the Perepolye dry valley in the Khoper River basin. This dry valley with the main trunk length of 6400 m was formed at the end of the Late Valdai Glaciation (MIS 2). The conditions required for the formation of a periglacial gully of such length were estimated with the GULTEM model. The critical velocity of erosion initiation was within the range 0.8-0.9 m/s, and the surface runoff depth was close to the recent one on the Yamal Peninsula (330 mm). The system of shallow hollows in the Perepolye catchment (the gullies formed at the end of the Moscow Glaciation, MIS 6) is denser and longer than the dry valley system, and the modelling estimates showed that the surface runoff during that period was almost 3.3 times more than the recent one on the Yamal Peninsula.
author2 This study was carried out with support of the Russian Science Foundation project 18-05-60147 “Extreme hydro-meteorological phenomena in the Kara Sea and the Arctic coast”
format Article in Journal/Newspaper
author Alexey Sidorchuk Yu.
Tatiana Matveeva A.
author_facet Alexey Sidorchuk Yu.
Tatiana Matveeva A.
author_sort Alexey Sidorchuk Yu.
title Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
title_short Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
title_full Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
title_fullStr Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
title_full_unstemmed Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula
title_sort periglacial gully erosion on the east european plain and its recent analog at the yamal peninsula
publisher Russian Geographical Society
publishDate 2020
url https://ges.rgo.ru/jour/article/view/1043
https://doi.org/10.24057/2071-9388-2019-01
long_lat ENVELOPE(69.873,69.873,70.816,70.816)
ENVELOPE(78.716,78.716,67.472,67.472)
geographic Arctic
Yamal Peninsula
Tazovsky
geographic_facet Arctic
Yamal Peninsula
Tazovsky
genre Antarctic Science
Arctic
Arctic
Permafrost and Periglacial Processes
Polar Research
Yamal Peninsula
genre_facet Antarctic Science
Arctic
Arctic
Permafrost and Periglacial Processes
Polar Research
Yamal Peninsula
op_source GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY; Vol 13, No 1 (2020); 183-194
2542-1565
2071-9388
op_relation https://ges.rgo.ru/jour/article/view/1043/450
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Borisova O.K., Sidorchuk A.Yu. and Panin A.V. (2006). Palaeohydrology of the Seim River basin, Mid-Russian Upland, based on palaeochannel morphology and palynological data. Catena, 66, 53-78. DOI:10.1016/j.catena.2005.07.010.
Bulygina O.N., Razuvayev V.N., and Aleksandrova T.M. (2008). Description of the data set of daily air temperature and precipitation at meteorological stations in Russia and the former USSR (TTTR). Certificate of State Registration of the Database № 2014620942 (in Russian).
Carlston C.W. (1963). Drainage density and streamflow. Geological Survey Professional Paper, 422.
Conway S., de Haas T., and Harrison T.N. (2019). Martian gullies: a comprehensive review of observations, mechanisms and insights from Earth analogues. Geological Society London Special Publications, 467, 7-66. DOI:10.1144/SP467.14.
Dee D.P. and Uppala S.M. (2009). Variational bias correction of satellite radiance data in the ERA–Interim reanalysis. Quarterly Journal of the Royal Meteorological Society, 135, 1830-1841. DOI:10.1002/qj.493.
Dee D.P., Uppala S.M., Simmons A.J., Berrisford P., et. al. (2011). The ERA–Interim reanalysis: Configuration and performance of the data assimilation system. Quarterly Journal of the Royal Meteorological Society, 137(656), 553-597. DOI:10.1002/qj.828.
Dickson J.L., Head J.W., Levy J.S., Morgan G.A. and Marchant D.R. (2019). Gully formation in the McMurdo Dry Valleys, Antarctica: multiple sources of water, temporal sequence and relative importance in gully erosion and deposition processes. Geological Society London Special Publications, 467, 289-314. DOI:10.1144/SP467.4.
Donat M.G., Sillmann J., Wild S., Alexander L.V., Lippmann T. and Zwiers F.W. (2014). Consistency of temperature and precipitation extremes across various global gridded in situ and reanalysis datasets. Journal of Climate, 27(13), 5019-5035. DOI:10.1175/JCLI-D-13-00405.1.
Eremenko E.A. and Panin A.V. (2011). An origin of the net of hollows in the central and southern regions of the East European Plain. Vestnik Moskovskogo Universiteta, Seriya 5, Geografiya, 3, 59-66 (in Russian).
Fortier D., Allard M. and Shur Y. (2007). Observation of rapid drainage system development by thermal erosion of ice wedges on Bylot island, Canadian Arctic Archipelago. Permafrost and Periglacial Processes, 18(3), 229-243. DOI:10.1002/ppp.595.
Gartsman I.N. (1968). River network and basin outflow in the southern Far East. Trudy DVNIGMI, 27, 15-22 (in Russian).
Gelfan A.N. (1999). Model of formation of river flow during snowmelt and rain. In: A. Sidorchuk and A. Baranov, eds., Erosion processes of central Yamal. St. Petersburg: RNII KPN, 205-225 (in Russian).
Godin E. and Fortier D. (2012). Geomorphology of a thermo-erosion gully, Bylot Island, Nunavut, Canada. Canadian Journal of Earth Sciences, 49(8), 979-986. DOI:10.1139/e2012-015.
Gregory K.J. (1966). Dry valleys and the composition of the drainage net. Journal of Hydrology, 4, 327-340. DOI:10.1016/0022-1694(66)90096-5.
Gregory K.J. and Walling D.E. (1968). The variation of drainage density within a catchment. International Association of Scientific Hydrology Bulletin, 13(2), 61-68. DOI:10.1080/02626666809493583.
Horton R.E. (1945). Erosional development of streams and their drainage basins; hydrophysical approach to quantitative morphology. Bulletin of the Geological Society of America, 56, 275-370. DOI:10.1130/0016-7606(1945)56[275:EDOSAT]2.0.CO;2
Hošek J., Prach J., Křížek M., Šída P., Moska P. and Pokorný P. (2019). Buried Late Weichselian thermokarst landscape discovered in the Czech Republic, central Europe. Boreas, 48(4), 988-1005. DOI:10.1111/bor.12404.
Knighton D. (1984). Fluvial Forms and Processes. London: Edward Arnold.
Komarov V.D., Makarova T.T and Sinegub E.S. (1969). Calculation of the hydrograph of floods of small lowland rivers based on thaw intensity data. Proceedings of the Hydrometeorological Center of the USSR, 37, 3-30 (in Russian).
Konstantinova G.S. (1973). The peculiarity of the erosion relief of the Yamal interfluve. In: Soil erosion and channel processes, 3. Moscow: Izdatelstvo MGU, 105-115 (in Russian).
Kosov B.F. and Konstantinova G.S. (1970). Features of ravine erosion in the tundra. In: Soil erosion and channel processes, 1. Moscow: Izdatelstvo MGU, 157-161 (in Russian).
Kosov B.F., Nikol’skaya I.I. and Zorina Ye.F. (1978). Experimental studies of ravine formation. In: N.I. Makkaveev, ed., Experimental geomorphology, 3. Moscow: Izdatelstvo MGU, 113-140 (in Russian).
Larsen A., Heckmann T., Larsen J.R. and Bork H.-R. (2016). Gully catchments as a sediment sink, not just a source: Results from a long-term (~12,500 year) sediment budget. Earth Surface Processes and Landforms, 41(4), 486-498. DOI:10.1002/esp.3839.
Levy J., Head J., and Marchant D. (2008). The role of thermal contraction crack polygons in cold-desert fluvial systems. Antarctic Science, 20(6), 565-579. DOI:10.1017/S0954102008001375.
Lindsay R., Wensnahan M., Schweiger A., and Zhang J. (2014). Evaluation of seven different atmospheric reanalysis products in the Arctic. Journal of Climate, 27(7), 2588-2606. DOI:10.1175/JCLI-D-13-00014.1.
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https://ges.rgo.ru/jour/article/view/1043
doi:10.24057/2071-9388-2019-01
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op_doi https://doi.org/10.24057/2071-9388-2019-01
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spelling ftjges:oai:oai.gesj.elpub.ru:article/1043 2023-05-15T14:14:53+02:00 Periglacial gully erosion on the east European plain and its recent analog at the Yamal peninsula Alexey Sidorchuk Yu. Tatiana Matveeva A. This study was carried out with support of the Russian Science Foundation project 18-05-60147 “Extreme hydro-meteorological phenomena in the Kara Sea and the Arctic coast” 2020-04-01 application/pdf https://ges.rgo.ru/jour/article/view/1043 https://doi.org/10.24057/2071-9388-2019-01 eng eng Russian Geographical Society https://ges.rgo.ru/jour/article/view/1043/450 Bettis III E.A. and Thompson D.M. (1985). Gully Erosion. Rangelands, 7(2), 70-72. Betts A.K., Köhler M. and Zhang Y. (2009). Comparison of river basin hydrometeorology in ERA–Interim and ERA–40 reanalyses with observations. Journal of Geophysical Research: Atmospheres, 114, D02101. DOI:10.1029/2008JD010761. Bobrovitskaya N.N., Baranov A.V., Vasilenko N.N. and Zubkova K.M. (1999). Hydrological conditions. In: A. Sidorchuk and A. Baranov, eds., Erosion processes of central Yamal. St. Petersburg: RNII KPN, 90-105 (in Russian). Borisova O.K., Sidorchuk A.Yu. and Panin A.V. (2006). Palaeohydrology of the Seim River basin, Mid-Russian Upland, based on palaeochannel morphology and palynological data. Catena, 66, 53-78. DOI:10.1016/j.catena.2005.07.010. Bulygina O.N., Razuvayev V.N., and Aleksandrova T.M. (2008). Description of the data set of daily air temperature and precipitation at meteorological stations in Russia and the former USSR (TTTR). Certificate of State Registration of the Database № 2014620942 (in Russian). Carlston C.W. (1963). Drainage density and streamflow. Geological Survey Professional Paper, 422. Conway S., de Haas T., and Harrison T.N. (2019). Martian gullies: a comprehensive review of observations, mechanisms and insights from Earth analogues. Geological Society London Special Publications, 467, 7-66. DOI:10.1144/SP467.14. Dee D.P. and Uppala S.M. (2009). Variational bias correction of satellite radiance data in the ERA–Interim reanalysis. Quarterly Journal of the Royal Meteorological Society, 135, 1830-1841. DOI:10.1002/qj.493. Dee D.P., Uppala S.M., Simmons A.J., Berrisford P., et. al. (2011). The ERA–Interim reanalysis: Configuration and performance of the data assimilation system. Quarterly Journal of the Royal Meteorological Society, 137(656), 553-597. DOI:10.1002/qj.828. Dickson J.L., Head J.W., Levy J.S., Morgan G.A. and Marchant D.R. (2019). Gully formation in the McMurdo Dry Valleys, Antarctica: multiple sources of water, temporal sequence and relative importance in gully erosion and deposition processes. Geological Society London Special Publications, 467, 289-314. DOI:10.1144/SP467.4. Donat M.G., Sillmann J., Wild S., Alexander L.V., Lippmann T. and Zwiers F.W. (2014). Consistency of temperature and precipitation extremes across various global gridded in situ and reanalysis datasets. Journal of Climate, 27(13), 5019-5035. DOI:10.1175/JCLI-D-13-00405.1. Eremenko E.A. and Panin A.V. (2011). An origin of the net of hollows in the central and southern regions of the East European Plain. Vestnik Moskovskogo Universiteta, Seriya 5, Geografiya, 3, 59-66 (in Russian). Fortier D., Allard M. and Shur Y. (2007). Observation of rapid drainage system development by thermal erosion of ice wedges on Bylot island, Canadian Arctic Archipelago. Permafrost and Periglacial Processes, 18(3), 229-243. DOI:10.1002/ppp.595. Gartsman I.N. (1968). River network and basin outflow in the southern Far East. Trudy DVNIGMI, 27, 15-22 (in Russian). Gelfan A.N. (1999). Model of formation of river flow during snowmelt and rain. In: A. Sidorchuk and A. Baranov, eds., Erosion processes of central Yamal. St. Petersburg: RNII KPN, 205-225 (in Russian). Godin E. and Fortier D. (2012). Geomorphology of a thermo-erosion gully, Bylot Island, Nunavut, Canada. Canadian Journal of Earth Sciences, 49(8), 979-986. DOI:10.1139/e2012-015. Gregory K.J. (1966). Dry valleys and the composition of the drainage net. Journal of Hydrology, 4, 327-340. DOI:10.1016/0022-1694(66)90096-5. Gregory K.J. and Walling D.E. (1968). The variation of drainage density within a catchment. International Association of Scientific Hydrology Bulletin, 13(2), 61-68. DOI:10.1080/02626666809493583. Horton R.E. (1945). Erosional development of streams and their drainage basins; hydrophysical approach to quantitative morphology. Bulletin of the Geological Society of America, 56, 275-370. DOI:10.1130/0016-7606(1945)56[275:EDOSAT]2.0.CO;2 Hošek J., Prach J., Křížek M., Šída P., Moska P. and Pokorný P. (2019). Buried Late Weichselian thermokarst landscape discovered in the Czech Republic, central Europe. Boreas, 48(4), 988-1005. DOI:10.1111/bor.12404. Knighton D. (1984). Fluvial Forms and Processes. London: Edward Arnold. Komarov V.D., Makarova T.T and Sinegub E.S. (1969). Calculation of the hydrograph of floods of small lowland rivers based on thaw intensity data. Proceedings of the Hydrometeorological Center of the USSR, 37, 3-30 (in Russian). Konstantinova G.S. (1973). The peculiarity of the erosion relief of the Yamal interfluve. In: Soil erosion and channel processes, 3. Moscow: Izdatelstvo MGU, 105-115 (in Russian). Kosov B.F. and Konstantinova G.S. (1970). Features of ravine erosion in the tundra. In: Soil erosion and channel processes, 1. Moscow: Izdatelstvo MGU, 157-161 (in Russian). Kosov B.F., Nikol’skaya I.I. and Zorina Ye.F. (1978). Experimental studies of ravine formation. In: N.I. Makkaveev, ed., Experimental geomorphology, 3. Moscow: Izdatelstvo MGU, 113-140 (in Russian). Larsen A., Heckmann T., Larsen J.R. and Bork H.-R. (2016). Gully catchments as a sediment sink, not just a source: Results from a long-term (~12,500 year) sediment budget. Earth Surface Processes and Landforms, 41(4), 486-498. DOI:10.1002/esp.3839. Levy J., Head J., and Marchant D. (2008). The role of thermal contraction crack polygons in cold-desert fluvial systems. Antarctic Science, 20(6), 565-579. DOI:10.1017/S0954102008001375. Lindsay R., Wensnahan M., Schweiger A., and Zhang J. (2014). Evaluation of seven different atmospheric reanalysis products in the Arctic. Journal of Climate, 27(7), 2588-2606. DOI:10.1175/JCLI-D-13-00014.1. Matoshko A.V. (2012). Balkas – a new look at a common landform of the East European Plain from a Quaternary perspective. Earth Surface Processes and Landforms, 37, 1489-1500, DOI:10.1002/esp.3255. Matveeva T.A., Gushchina D.Y. and Zolina O. (2015). Large-scale indicators of extreme precipitation in coastal natural-economic zones of the European part of Russia. Russian Meteorology and Hydrology, 40(11), 722-730. DOI:10.3103/S1068373915110023. Panin A.V. and Sidorchuk A.Yu. (2006). Macrobends («large meanders»): The problems of origin and interpretation. Vestnik Moskovskogo universiteta, Seriya 5, Geografiya, 6, 14-22 (in Russian). Panin A.V., Matlahova E.Y., Belyaev Y.R., Bulyart J.-P., Dubis L.F., Murray A., Pakhomova O.M., Selezneva E.V. and Filippov V.V. (2011). Sedimentation and formation of terraces in river valleys of the central Russian Plain during the second half of the Late Pleistocene. Bulletin of the Commission for Study of the Quaternary, 71, 47-74 (in Russian). Popov Ye.G. (1956). Analysis of river flow formation. Leningrad: Gidrometeoizdat (in Russian). Poznanin V.L. (2012). Erosion processes in cryolitzone. Space and Time, 1(7), 127-132 (in Russian). Prosser J.P., Chappell J.M.A. and Gillespie R. (1994). Holocene valley aggradation and gully erosion in headwater catchments, South-Eastern Highlands of Australia. Earth Surface Processes and Landforms, 19, 465-480.DOI:10.1002/esp.3290190507 Sidorchuk A. (1996). Gully erosion and thermoerosion on the Yamal Peninsula. In: O. Slaymaker, ed., Geomorphic Hazards. 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Moscow: Izdatelstvo MGU (in Russian). https://ges.rgo.ru/jour/article/view/1043 doi:10.24057/2071-9388-2019-01 Authors who publish with this journal agree to the following terms:Authors retain copyright and grant the journal the right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.Authors can enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgment of its initial publication in this journal.Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).The information and opinions presented in the Journal reflect the views of the authors and not of the Journal or its Editorial Board or the Publisher. 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Авторы, публикующие в данном журнале, соглашаются со следующим:Авторы сохраняют за собой авторские права на работу и предоставляют журналу право первой публикации работы на условиях лицензии Creative Commons Attribution License, которая позволяет другим распространять данную работу с обязательным сохранением ссылок на авторов оригинальной работы и оригинальную публикацию в этом журнале.Авторы сохраняют право заключать отдельные контрактные договорённости, касающиеся не-эксклюзивного распространения версии работы в опубликованном здесь виде (например, размещение ее в институтском хранилище, публикацию в книге), со ссылкой на ее оригинальную публикацию в этом журнале.Авторы имеют право размещать их работу CC-BY GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY; Vol 13, No 1 (2020); 183-194 2542-1565 2071-9388 The Yamal Peninsula;active gullies;East European Plain;periglacial erosion;gully erosion and thermoerosion modelling;estimates of past surface runof info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2020 ftjges https://doi.org/10.24057/2071-9388-2019-01 https://doi.org/10.1029/2008JD010761 https://doi.org/10.1016/j.catena.2005.07.010 https://doi.org/10.1144/SP467.14 https://doi.org/10.1002/qj.493 https://doi.org/10.1002/qj.828 https://doi.org/10.1144 2021-05-21T07:34:36Z The net of dry valleys, gullies and shallow hollows is typical for the East European Plain. Dense vegetation usually covers their bottoms and slopes, so the modern erosion there is negligible in the pristine conditions. This erosion landscape formed in periglacial conditions during the terminations of the last two glaciations. The same kind of the erosion landscape is typical for the Arctic regions, especially for the Yamal, Gydan, and Tazovsky peninsulas. The size and the density of such valleys and gullies are quite similar to those existing on the East European Plain, but these erosion features are active there, especially in the conditions of natural or anthropogenic deterioration of the vegetation cover. As the density of dry valley network is an indicator of hydrological conditions in the river basin, the landscapes of the Arctic regions can be used as the modern analogs of the territories with the past periglacial erosion.The recent hydrological characteristics of the west-central Yamal Peninsula were used to estimate the parameters of erosion network at the Khoper River basin, formed in periglacial conditions. For these purposes gully erosion and thermoerosion model GULTEM was verified and calibrated based on the observation of the modern processes on the Yamal Peninsula. The meteorological characteristics were taken from ERA-Interim Reanalysis grid. To calculate the flow characteristics a synthetic hydrological model was used. These verified and calibrated models were used to find the most suitable characteristics of climate and vegetation cover, which can explain the structure and density of the Perepolye dry valley in the Khoper River basin. This dry valley with the main trunk length of 6400 m was formed at the end of the Late Valdai Glaciation (MIS 2). The conditions required for the formation of a periglacial gully of such length were estimated with the GULTEM model. The critical velocity of erosion initiation was within the range 0.8-0.9 m/s, and the surface runoff depth was close to the recent one on the Yamal Peninsula (330 mm). The system of shallow hollows in the Perepolye catchment (the gullies formed at the end of the Moscow Glaciation, MIS 6) is denser and longer than the dry valley system, and the modelling estimates showed that the surface runoff during that period was almost 3.3 times more than the recent one on the Yamal Peninsula. Article in Journal/Newspaper Antarctic Science Arctic Arctic Permafrost and Periglacial Processes Polar Research Yamal Peninsula Geography, Environment, Sustainability (E-Journal) Arctic Yamal Peninsula ENVELOPE(69.873,69.873,70.816,70.816) Tazovsky ENVELOPE(78.716,78.716,67.472,67.472) GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY 13 1 183 194

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