Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town

The object of research is syncryogenic Holocene strata on the coast of the Onemen Bay, 2 km from the town of Anadyr. In July 2017, the outcrop of the first marine terrace uncovered by strong storms was examined. The stratigraphy of the outcrop was represented mainly by sandy loam (5–7 m thick) cover...

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Published in:Ice and Snow
Main Authors: N. Budantseva A., Yu. Vasil'chuk A., Н. Буданцева А., Ю. Васильчук К.
Format: Article in Journal/Newspaper
Language:Russian
Published: IGRAS 2019
Subjects:
deuterium excess;Eastern Chukotka;Holocene;hydrogen and oxygen isotopes;ice wedges;peatland;radiocarbon age;reconstruction of paleotemperature;winter air temperature
Восточная Чукотка;голоцен;дейтериевый эксцесс;зимняя температура воздуха;изотопы водорода и кислорода;палеотемпературные реконструкции;повторно-жильный лёд;радиоуглеродный возраст;торфяник
Anadyr
Anadyr’
Anadyr'
Arctic
Berichte zur Polar- und Meeresforschung
Chukotka
Permafrost and Periglacial Processes
Thermokarst
ЧУКОТКА
Online Access:https://ice-snow.igras.ru/jour/article/view/544
https://doi.org/10.15356/2076-6734-2019-1-93-102
id ftjias:oai:oai.ice.elpub.ru:article/544
record_format openpolar
institution Open Polar
collection Ice and Snow (E-Journal)
op_collection_id ftjias
language Russian
topic deuterium excess;Eastern Chukotka;Holocene;hydrogen and oxygen isotopes;ice wedges;peatland;radiocarbon age;reconstruction of paleotemperature;winter air temperature
Восточная Чукотка;голоцен;дейтериевый эксцесс;зимняя температура воздуха;изотопы водорода и кислорода;палеотемпературные реконструкции;повторно-жильный лёд;радиоуглеродный возраст;торфяник
spellingShingle deuterium excess;Eastern Chukotka;Holocene;hydrogen and oxygen isotopes;ice wedges;peatland;radiocarbon age;reconstruction of paleotemperature;winter air temperature
Восточная Чукотка;голоцен;дейтериевый эксцесс;зимняя температура воздуха;изотопы водорода и кислорода;палеотемпературные реконструкции;повторно-жильный лёд;радиоуглеродный возраст;торфяник
N. Budantseva A.
Yu. Vasil'chuk A.
Н. Буданцева А.
Ю. Васильчук К.
Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
topic_facet deuterium excess;Eastern Chukotka;Holocene;hydrogen and oxygen isotopes;ice wedges;peatland;radiocarbon age;reconstruction of paleotemperature;winter air temperature
Восточная Чукотка;голоцен;дейтериевый эксцесс;зимняя температура воздуха;изотопы водорода и кислорода;палеотемпературные реконструкции;повторно-жильный лёд;радиоуглеродный возраст;торфяник
description The object of research is syncryogenic Holocene strata on the coast of the Onemen Bay, 2 km from the town of Anadyr. In July 2017, the outcrop of the first marine terrace uncovered by strong storms was examined. The stratigraphy of the outcrop was represented mainly by sandy loam (5–7 m thick) covered by peat (1–1.5 m) and underlain by sand. Numerous ice wedges were opened in the upper part of this outcrop. Along with that another outcropping of transect of a lakemarsh basin represented by a peat bog of 2–2.5 m thick underlain by sandy loam was also investigated. Ice wedges occur below the polygonal trenches. The present-day narrow ice wedges were found in the upper part of the peat bog. Two representative fragments of both the above outcrops were thoroughly examined. Radiocarbon dating had shown that accumulation of peat on surface of the first marine terrace started in early Holocene (about 8 ka BP). Accumulation of peatland within the lake-marsh basin was also dated to the beginning of the Holocene (about 9 ka BP). In the middle of the Holocene, it was most likely interrupted as a result of thermokarst processes and bogging of the surface. Formation of peatlands in Chukotka during the Holocene is known to be accompanied by active growth of the ice wedges inside them, so the age of the wedges studied by us was estimated as the beginning of the Holocene. The analysis of stable oxygen and hydrogen isotopes in the Holocene and the modern ice wedges had allowed establishing mainly the atmospheric type of moisture feeding of the wedges (due to melted snow) and lack of noticeable isotope fractionation during the ice formation. It has been found that δ18О and δ2Н values in the Holocene ice wedges were lower than in the modern wedges and snow by an average 2–3 and 7–12 ‰, respectively. Paleotemperature reconstructions performed on the basis of isotopeoxygen data showed that the air temperature of the coldest winter month in the first half of the Holocene in the Onemen Bay area was lower than the present-day ones by an ...
format Article in Journal/Newspaper
author N. Budantseva A.
Yu. Vasil'chuk A.
Н. Буданцева А.
Ю. Васильчук К.
author_facet N. Budantseva A.
Yu. Vasil'chuk A.
Н. Буданцева А.
Ю. Васильчук К.
author_sort N. Budantseva A.
title Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
title_short Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
title_full Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
title_fullStr Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
title_full_unstemmed Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town
title_sort winter air temperature in holocene reconstructed from the ice wedges stable water isotopes near anadyr town
publisher IGRAS
publishDate 2019
url https://ice-snow.igras.ru/jour/article/view/544
https://doi.org/10.15356/2076-6734-2019-1-93-102
long_lat ENVELOPE(177.510,177.510,64.734,64.734)
ENVELOPE(176.233,176.233,64.882,64.882)
geographic Anadyr
Anadyr’
geographic_facet Anadyr
Anadyr’
genre Anadyr
Anadyr'
Arctic
Berichte zur Polar- und Meeresforschung
Chukotka
Permafrost and Periglacial Processes
Thermokarst
ЧУКОТКА
genre_facet Anadyr
Anadyr'
Arctic
Berichte zur Polar- und Meeresforschung
Chukotka
Permafrost and Periglacial Processes
Thermokarst
ЧУКОТКА
op_source Ice and Snow; Том 59, № 1 (2019); 93-102
Лёд и Снег; Том 59, № 1 (2019); 93-102
2412-3765
2076-6734
10.15356/2076-6734-2019-1
op_relation https://ice-snow.igras.ru/jour/article/view/544/305
Васильчук Ю.К. Изотопно-кислородный состав подземных льдов (опыт палеогеокриологических реконструкций): В 2 т. Т. 1. М.: изд. отдела теоретических проблем РАН–МГУ, 1992. 420 с.
Meyer H., Opel T., Laepple T., Dereviagin A.Y., Hoffmann K., Werner M. Long-term winter warming trend in the Siberian Arctic during the mid- to late Holocene // Nature Geoscience. 2015. № 8. Р. 122–125.
Opel T., Meyer H., Wetterich S., Laepple T., Dereviagin A., Murton J. Ice wedges as archives of winter paleoclimate: A review // Permafrost and Periglacial Processes. 2018. V. 29. № 3. P. 199–209.
Schwamborn G., Fedorov G., Schirrmeister L., Meyer H., Hubberten H.W. Periglacial sediment variations controlled by late Quaternary climate and lake level change at Elgygytgyn Crater, Arctic Siberia // Boreas. 2008. V. 37. № 1. Р. 55–65.
Schwamborn G., Meyer H., Fedorov G., Schirrmeister L., Hubberten H.W. Ground ice and slope sediments archiving late Quaternary paleoenvironment and paleoclimate signals at the margins of El'gygytgyn Impact Crater, NE Siberia // Quaternary Research. 2006. V. 66. Р. 259–272.
Новейшие отложения и палеогеография плейстоцена Чукотки / Под. ред. П.И. Каплина. М.: Наука, 1980. 295 с.
Lozhkin A.V., Anderson P.M. Forest or no forest: implications of the vegetation record for climatic stability in Western Beringia during Oxygen Isotope Stage 3 // Quaternary Science Reviews. 2011. V. 30. Р. 2160–2181.
Котов А.Н. Особенности криолитогенеза в зоне абляции позднеплейстоценовых ледников // История фундаментальных исследований криосферы Земли в Арктике и Субарктике. Новосибирск: Наука, 1997. C. 249–259.
Котов А.Н. Аласный и ледовый комплексы отложений северо-западной Чукотки (побережье Восточно-Сибирского моря) // Криосфера Земли. 1998. Т. 2. № 1. С. 11–18.
Котов А.Н. Отражение климатических ритмов в морфологии рельефа и строении криолитогенных отложений долины р. Танюрер (Чукотка) // Изменение природной среды Берингии в четвертичный период. Магадан: Чукотский филиал Северо-Восточного комплексного науч.- исслед. ин‑та ДВО РАН, 1998. С. 133–153.
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Vasil'chuk Yu.K., Trofimov V.T. Debated problems of paleocryology of the Pleistocene and Holocene of Western Siberia in light of new data // Moscow University geology Bulletin. Published Allerton Press Inc., New York. 1984. V. 39. № 3. P. 67–80.
Vasil'chuk Yu.K., Yesikov A.D., Oprunenko Yu.F., Petrova Ye.A., Vasil'chuk A.C., Sulerzhitskiy L.D. New data of stable oxygen isotopes composition in syngenetic Late Pleistocene ice wedge of the lower Kolyma River // Transactions of the USSR Academy of Sciences. Earth Science Sections. Published by Scripta Technica, Inc. A Wiley Company. New York. 1985. V. 281. № 2. P. 91–94.
Dansgaard W. Stable isotopes in precipitation // Tellus. 1964. V. 16. № 4. P. 436–468.
Vasil'chuk Yu., Vasil'chuk A. Oxygen-isotope composition dynamics of Northern Eurasia cryosphere during last 40 kyr // Summer school on isotope effects as tools in basic and environmental research. Roskilde. Denmark. June 24–28. 1995. Abstracts. Publications
of University of Roskilde, 1995. P. 41–42.
Fukuda M., Nagaoka D., Saijyo K., Nakamura T., Kunitsky V. Radiocarbon dating results of organic materials obtained from Siberian permafrost areas // Reports of Institute of Low Temperature Science. Sapporo: Hokkaido University, 1997. P. 17–28.
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Meyer H., Dereviagin A., Siegert C., Schirmieister L., Hubberten H.W. Palaeoclimate reconstruction on Big Lyakhovsky Island. North Siberia – hydrogen and oxygen isotopes in ice wedges // Permafrost and Periglacial Processes. 2002. V. 13. P. 91–105.
Meyer H. Late Quaternary climate history of Northern Siberia – evidence from ground ice (Die spätquartär Klimageschichte Nordsibiriens – Ergebnisse aus Untersuchungen an Grundeis) // Berichte zur Polar- und Meeresforschung. 2003. № 461. 112 p.
Васильчук Ю.К., Котляков В.М. Основы изотопной геокриологии и гляциологии. М.: Изд‑во МГУ, 2000. 616 с.
Важенина Л.Н., Ложкин А.В. Нижнеголоценовые торфяники северо-востока Сибири // Изв. РАН. Сер. геогр. 2013. № 5. С. 74–84.
Иванов В.Ф. Четвертичные отложения побережья Восточной Чукотки. Владивосток, 1986. 138 с.
Электронный ресурс: http://meteo.ru/data/156-temperature.
Vasil'chuk Yu.K., Budantseva N.A., Vasil'chuk A.C., Maslakov A.A., Chizhova Ju.N. Oxygen isotope composition of Holocene ice wedges of Eastern Chukotka // Doklady Earth Sciences. 2018. V. 480. Pt. 2. P. 759–763.
Kanevskiy M., Shur Y., Jorgenson T., Brown D.R.N., Moskalenko N., Brown J., Walker D.A., Raynolds M.K., Buchhorn M. Degradation and stabilization of ice wedges: Implications for assessing risk of thermokarst in northern Alaska // Geomorphology. 2017. № 297. P. 20–42.
https://ice-snow.igras.ru/jour/article/view/544
doi:10.15356/2076-6734-2019-1-93-102
op_rights Authors who publish with this journal agree to the following terms:Authors retain copyright and grant the journal 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 are able to 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 acknowledgement 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).
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spelling ftjias:oai:oai.ice.elpub.ru:article/544 2023-05-15T13:24:37+02:00 Winter air temperature in Holocene reconstructed from the ice wedges stable water isotopes near Anadyr town Реконструкция зимней температуры воздуха в голоцене по стабильным изотопам из ледяных жил в районе города Анадырь N. Budantseva A. Yu. Vasil'chuk A. Н. Буданцева А. Ю. Васильчук К. 2019-03-20 application/pdf https://ice-snow.igras.ru/jour/article/view/544 https://doi.org/10.15356/2076-6734-2019-1-93-102 rus rus IGRAS https://ice-snow.igras.ru/jour/article/view/544/305 Васильчук Ю.К. Изотопно-кислородный состав подземных льдов (опыт палеогеокриологических реконструкций): В 2 т. Т. 1. М.: изд. отдела теоретических проблем РАН–МГУ, 1992. 420 с. Meyer H., Opel T., Laepple T., Dereviagin A.Y., Hoffmann K., Werner M. Long-term winter warming trend in the Siberian Arctic during the mid- to late Holocene // Nature Geoscience. 2015. № 8. Р. 122–125. Opel T., Meyer H., Wetterich S., Laepple T., Dereviagin A., Murton J. Ice wedges as archives of winter paleoclimate: A review // Permafrost and Periglacial Processes. 2018. V. 29. № 3. P. 199–209. Schwamborn G., Fedorov G., Schirrmeister L., Meyer H., Hubberten H.W. Periglacial sediment variations controlled by late Quaternary climate and lake level change at Elgygytgyn Crater, Arctic Siberia // Boreas. 2008. V. 37. № 1. Р. 55–65. Schwamborn G., Meyer H., Fedorov G., Schirrmeister L., Hubberten H.W. Ground ice and slope sediments archiving late Quaternary paleoenvironment and paleoclimate signals at the margins of El'gygytgyn Impact Crater, NE Siberia // Quaternary Research. 2006. V. 66. Р. 259–272. Новейшие отложения и палеогеография плейстоцена Чукотки / Под. ред. П.И. Каплина. М.: Наука, 1980. 295 с. Lozhkin A.V., Anderson P.M. Forest or no forest: implications of the vegetation record for climatic stability in Western Beringia during Oxygen Isotope Stage 3 // Quaternary Science Reviews. 2011. V. 30. Р. 2160–2181. Котов А.Н. Особенности криолитогенеза в зоне абляции позднеплейстоценовых ледников // История фундаментальных исследований криосферы Земли в Арктике и Субарктике. Новосибирск: Наука, 1997. C. 249–259. Котов А.Н. Аласный и ледовый комплексы отложений северо-западной Чукотки (побережье Восточно-Сибирского моря) // Криосфера Земли. 1998. Т. 2. № 1. С. 11–18. Котов А.Н. Отражение климатических ритмов в морфологии рельефа и строении криолитогенных отложений долины р. Танюрер (Чукотка) // Изменение природной среды Берингии в четвертичный период. Магадан: Чукотский филиал Северо-Восточного комплексного науч.- исслед. ин‑та ДВО РАН, 1998. С. 133–153. Королев С.В. Находка в долине р. Амгуэмы позднеплейстоценового глетчерного льда (Северная Чукотка) // ДАН. 1993. Т. 329. № 2. С. 195–198. Васильчук Ю.К. Корреляция изотопно-кислородного состава повторно-жильных льдов со среднезимними и среднеянварскими температурами воздуха // Изотопы в гидросфере. Тезисы докладов 3‑го Всес. симпозиума. М.: Ин‑т водных проблем АН СССР, 1989. С. 82–83. Vasil'chuk Yu.K., Trofimov V.T. Debated problems of paleocryology of the Pleistocene and Holocene of Western Siberia in light of new data // Moscow University geology Bulletin. Published Allerton Press Inc., New York. 1984. V. 39. № 3. P. 67–80. Vasil'chuk Yu.K., Yesikov A.D., Oprunenko Yu.F., Petrova Ye.A., Vasil'chuk A.C., Sulerzhitskiy L.D. New data of stable oxygen isotopes composition in syngenetic Late Pleistocene ice wedge of the lower Kolyma River // Transactions of the USSR Academy of Sciences. Earth Science Sections. Published by Scripta Technica, Inc. A Wiley Company. New York. 1985. V. 281. № 2. P. 91–94. Dansgaard W. Stable isotopes in precipitation // Tellus. 1964. V. 16. № 4. P. 436–468. Vasil'chuk Yu., Vasil'chuk A. Oxygen-isotope composition dynamics of Northern Eurasia cryosphere during last 40 kyr // Summer school on isotope effects as tools in basic and environmental research. Roskilde. Denmark. June 24–28. 1995. Abstracts. Publications of University of Roskilde, 1995. P. 41–42. Fukuda M., Nagaoka D., Saijyo K., Nakamura T., Kunitsky V. Radiocarbon dating results of organic materials obtained from Siberian permafrost areas // Reports of Institute of Low Temperature Science. Sapporo: Hokkaido University, 1997. P. 17–28. Nikolayev V.I., Mikhalev D.V. An oxygen-isotope paleothermometer from ice in Siberian permafrost // Quaternary Research. 1995. V. 43. № 1. P. 14–21. Meyer H., Dereviagin A., Siegert C., Schirmieister L., Hubberten H.W. Palaeoclimate reconstruction on Big Lyakhovsky Island. North Siberia – hydrogen and oxygen isotopes in ice wedges // Permafrost and Periglacial Processes. 2002. V. 13. P. 91–105. Meyer H. Late Quaternary climate history of Northern Siberia – evidence from ground ice (Die spätquartär Klimageschichte Nordsibiriens – Ergebnisse aus Untersuchungen an Grundeis) // Berichte zur Polar- und Meeresforschung. 2003. № 461. 112 p. Васильчук Ю.К., Котляков В.М. Основы изотопной геокриологии и гляциологии. М.: Изд‑во МГУ, 2000. 616 с. Важенина Л.Н., Ложкин А.В. Нижнеголоценовые торфяники северо-востока Сибири // Изв. РАН. Сер. геогр. 2013. № 5. С. 74–84. Иванов В.Ф. Четвертичные отложения побережья Восточной Чукотки. Владивосток, 1986. 138 с. Электронный ресурс: http://meteo.ru/data/156-temperature. Vasil'chuk Yu.K., Budantseva N.A., Vasil'chuk A.C., Maslakov A.A., Chizhova Ju.N. Oxygen isotope composition of Holocene ice wedges of Eastern Chukotka // Doklady Earth Sciences. 2018. V. 480. Pt. 2. P. 759–763. Kanevskiy M., Shur Y., Jorgenson T., Brown D.R.N., Moskalenko N., Brown J., Walker D.A., Raynolds M.K., Buchhorn M. Degradation and stabilization of ice wedges: Implications for assessing risk of thermokarst in northern Alaska // Geomorphology. 2017. № 297. P. 20–42. https://ice-snow.igras.ru/jour/article/view/544 doi:10.15356/2076-6734-2019-1-93-102 Authors who publish with this journal agree to the following terms:Authors retain copyright and grant the journal 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 are able to 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 acknowledgement 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). Авторы, публикующие статьи в данном журнале, соглашаются на следующее:Авторы сохраняют за собой авторские права и предоставляют журналу право первой публикации работы, которая по истечении 6 месяцев после публикации автоматически лицензируется на условиях Creative Commons Attribution License , что позволяет другим распространять данную работу с обязательным сохранением ссылок на авторов оригинальной работы и оригинальную публикацию в этом журнале.Редакция журнала будет размещать принятую для публикации статью на сайте журнала до выхода её в свет (после утверждения к печати редколлегией журнала). Авторы также имеют право размещать их работу в сети Интернет (например в институтском хранилище или персональном сайте) до и во время процесса рассмотрения ее данным журналом, так как это может привести к продуктивному обсуждению и большему количеству ссылок на данную работу (См. The Effect of Open Access). CC-BY Ice and Snow; Том 59, № 1 (2019); 93-102 Лёд и Снег; Том 59, № 1 (2019); 93-102 2412-3765 2076-6734 10.15356/2076-6734-2019-1 deuterium excess;Eastern Chukotka;Holocene;hydrogen and oxygen isotopes;ice wedges;peatland;radiocarbon age;reconstruction of paleotemperature;winter air temperature Восточная Чукотка;голоцен;дейтериевый эксцесс;зимняя температура воздуха;изотопы водорода и кислорода;палеотемпературные реконструкции;повторно-жильный лёд;радиоуглеродный возраст;торфяник info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2019 ftjias https://doi.org/10.15356/2076-6734-2019-1-93-102 https://doi.org/10.15356/2076-6734-2019-1 2022-12-20T13:30:01Z The object of research is syncryogenic Holocene strata on the coast of the Onemen Bay, 2 km from the town of Anadyr. In July 2017, the outcrop of the first marine terrace uncovered by strong storms was examined. The stratigraphy of the outcrop was represented mainly by sandy loam (5–7 m thick) covered by peat (1–1.5 m) and underlain by sand. Numerous ice wedges were opened in the upper part of this outcrop. Along with that another outcropping of transect of a lakemarsh basin represented by a peat bog of 2–2.5 m thick underlain by sandy loam was also investigated. Ice wedges occur below the polygonal trenches. The present-day narrow ice wedges were found in the upper part of the peat bog. Two representative fragments of both the above outcrops were thoroughly examined. Radiocarbon dating had shown that accumulation of peat on surface of the first marine terrace started in early Holocene (about 8 ka BP). Accumulation of peatland within the lake-marsh basin was also dated to the beginning of the Holocene (about 9 ka BP). In the middle of the Holocene, it was most likely interrupted as a result of thermokarst processes and bogging of the surface. Formation of peatlands in Chukotka during the Holocene is known to be accompanied by active growth of the ice wedges inside them, so the age of the wedges studied by us was estimated as the beginning of the Holocene. The analysis of stable oxygen and hydrogen isotopes in the Holocene and the modern ice wedges had allowed establishing mainly the atmospheric type of moisture feeding of the wedges (due to melted snow) and lack of noticeable isotope fractionation during the ice formation. It has been found that δ18О and δ2Н values in the Holocene ice wedges were lower than in the modern wedges and snow by an average 2–3 and 7–12 ‰, respectively. Paleotemperature reconstructions performed on the basis of isotopeoxygen data showed that the air temperature of the coldest winter month in the first half of the Holocene in the Onemen Bay area was lower than the present-day ones by an ... Article in Journal/Newspaper Anadyr Anadyr' Arctic Berichte zur Polar- und Meeresforschung Chukotka Permafrost and Periglacial Processes Thermokarst ЧУКОТКА Ice and Snow (E-Journal) Anadyr ENVELOPE(177.510,177.510,64.734,64.734) Anadyr’ ENVELOPE(176.233,176.233,64.882,64.882) Ice and Snow 59 1 93 102

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