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Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia. / Ulrich, Mathias; Wetterich, Sebastian; Rudaya, Natalia et al.

In: Holocene, Vol. 27, No. 12, 01.05.2017, p. 1899-1913.

Research output: Contribution to journalArticlepeer-review

Harvard

Ulrich, M, Wetterich, S, Rudaya, N, Frolova, L, Schmidt, J, Siegert, C, Fedorov, AN & Zielhofer, C 2017, 'Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia', Holocene, vol. 27, no. 12, pp. 1899-1913. https://doi.org/10.1177/0959683617708454

APA

Ulrich, M., Wetterich, S., Rudaya, N., Frolova, L., Schmidt, J., Siegert, C., Fedorov, A. N., & Zielhofer, C. (2017). Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia. Holocene, 27(12), 1899-1913. https://doi.org/10.1177/0959683617708454

Vancouver

Ulrich M, Wetterich S, Rudaya N, Frolova L, Schmidt J, Siegert C et al. Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia. Holocene. 2017 May 1;27(12):1899-1913. doi: 10.1177/0959683617708454

Author

Ulrich, Mathias ; Wetterich, Sebastian ; Rudaya, Natalia et al. / Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia. In: Holocene. 2017 ; Vol. 27, No. 12. pp. 1899-1913.

BibTeX

@article{1e0671ac191e46b0be949f41d961ba2e,
title = "Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia",
abstract = "The reconstruction of Holocene thermokarst landform evolution is important to understand the potential impact of current global climate change on permafrost regions. A multi-proxy approach was applied to analyse the sedimentological and biogeochemical characteristics as well as pollen and lacustrine microfossils of a core profile drilled in a small pingo within a large Central Yakutian thermokarst basin (alas). Age–depth modelling with macrofossil 14C ages reveals high thermokarst deposit sedimentation rates and a complete thermokarst sequence spanning about 900 years during the mid-Holocene between ~6750 and 5870 cal. yr BP. In total, three stages of thermokarst landscape evolution have been identified. Thermokarst processes were initiated at ⩽6750 to 6500 cal. yr BP. Terrestrial conditions changed quickly to lacustrine conditions, and a thermokarst lake rapidly emerged and grew to an estimated size of 120–600 m diameter and 7.5–15 m depth during only ~150 years between ~6500 and 6350 cal. yr BP. The decline of thermokarst processes and lake decrease may have been affected by local hydrological conditions between ~6350 and 5870 cal. yr BP but ceased completely after 5870 cal. yr BP, likely due to climatic changes. Clear evidence for long-lasting and stable lacustrine conditions was not obtained. The study emphasises that short-term warming led to very active permafrost degradation and rapid but locally variable modification of alas and thermokarst evolution.",
keywords = "climate change, Eastern Siberia, Holocene thermal maximum, palaeolimnology, permafrost, thermokarst deposits, Climate change, Permafrost, Thermokarst deposits, Palaeolimnology, LATE QUATERNARY, NORTHERN SEWARD PENINSULA, EASTERN SIBERIA, ALASKA, LAKE, LANDSCAPE DYNAMICS, VARIABILITY, PERIGLACIAL LANDSCAPE, PERMAFROST DEGRADATION, BASIN",
author = "Mathias Ulrich and Sebastian Wetterich and Natalia Rudaya and Larisa Frolova and Johannes Schmidt and Christine Siegert and Fedorov, {Alexander N.} and Christoph Zielhofer",
year = "2017",
month = may,
day = "1",
doi = "10.1177/0959683617708454",
language = "English",
volume = "27",
pages = "1899--1913",
journal = "Holocene",
issn = "0959-6836",
publisher = "SAGE Publications Ltd",
number = "12",

}

RIS

TY - JOUR

T1 - Rapid thermokarst evolution during the mid-Holocene in Central Yakutia, Russia

AU - Ulrich, Mathias

AU - Wetterich, Sebastian

AU - Rudaya, Natalia

AU - Frolova, Larisa

AU - Schmidt, Johannes

AU - Siegert, Christine

AU - Fedorov, Alexander N.

AU - Zielhofer, Christoph

PY - 2017/5/1

Y1 - 2017/5/1

N2 - The reconstruction of Holocene thermokarst landform evolution is important to understand the potential impact of current global climate change on permafrost regions. A multi-proxy approach was applied to analyse the sedimentological and biogeochemical characteristics as well as pollen and lacustrine microfossils of a core profile drilled in a small pingo within a large Central Yakutian thermokarst basin (alas). Age–depth modelling with macrofossil 14C ages reveals high thermokarst deposit sedimentation rates and a complete thermokarst sequence spanning about 900 years during the mid-Holocene between ~6750 and 5870 cal. yr BP. In total, three stages of thermokarst landscape evolution have been identified. Thermokarst processes were initiated at ⩽6750 to 6500 cal. yr BP. Terrestrial conditions changed quickly to lacustrine conditions, and a thermokarst lake rapidly emerged and grew to an estimated size of 120–600 m diameter and 7.5–15 m depth during only ~150 years between ~6500 and 6350 cal. yr BP. The decline of thermokarst processes and lake decrease may have been affected by local hydrological conditions between ~6350 and 5870 cal. yr BP but ceased completely after 5870 cal. yr BP, likely due to climatic changes. Clear evidence for long-lasting and stable lacustrine conditions was not obtained. The study emphasises that short-term warming led to very active permafrost degradation and rapid but locally variable modification of alas and thermokarst evolution.

AB - The reconstruction of Holocene thermokarst landform evolution is important to understand the potential impact of current global climate change on permafrost regions. A multi-proxy approach was applied to analyse the sedimentological and biogeochemical characteristics as well as pollen and lacustrine microfossils of a core profile drilled in a small pingo within a large Central Yakutian thermokarst basin (alas). Age–depth modelling with macrofossil 14C ages reveals high thermokarst deposit sedimentation rates and a complete thermokarst sequence spanning about 900 years during the mid-Holocene between ~6750 and 5870 cal. yr BP. In total, three stages of thermokarst landscape evolution have been identified. Thermokarst processes were initiated at ⩽6750 to 6500 cal. yr BP. Terrestrial conditions changed quickly to lacustrine conditions, and a thermokarst lake rapidly emerged and grew to an estimated size of 120–600 m diameter and 7.5–15 m depth during only ~150 years between ~6500 and 6350 cal. yr BP. The decline of thermokarst processes and lake decrease may have been affected by local hydrological conditions between ~6350 and 5870 cal. yr BP but ceased completely after 5870 cal. yr BP, likely due to climatic changes. Clear evidence for long-lasting and stable lacustrine conditions was not obtained. The study emphasises that short-term warming led to very active permafrost degradation and rapid but locally variable modification of alas and thermokarst evolution.

KW - climate change

KW - Eastern Siberia

KW - Holocene thermal maximum

KW - palaeolimnology

KW - permafrost

KW - thermokarst deposits

KW - Climate change

KW - Permafrost

KW - Thermokarst deposits

KW - Palaeolimnology

KW - LATE QUATERNARY

KW - NORTHERN SEWARD PENINSULA

KW - EASTERN SIBERIA

KW - ALASKA

KW - LAKE

KW - LANDSCAPE DYNAMICS

KW - VARIABILITY

KW - PERIGLACIAL LANDSCAPE

KW - PERMAFROST DEGRADATION

KW - BASIN

UR - http://www.scopus.com/inward/record.url?scp=85042212621&partnerID=8YFLogxK

U2 - 10.1177/0959683617708454

DO - 10.1177/0959683617708454

M3 - Article

AN - SCOPUS:85042212621

VL - 27

SP - 1899

EP - 1913

JO - Holocene

JF - Holocene

SN - 0959-6836

IS - 12

ER -

ID: 10214901