Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores

Bol’shoy Lyakhovsky, the southernmost island of the New Siberian Archipelago, holds the longest record of palaeoenvironmental history in the non-glaciated Siberian Arctic preserved in permafrost. It stretches back to ~200 kyr before present and includes prominent last interglacial thermokarst and Ye...

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Main Authors: Schwamborn, Georg, Schirrmeister, Lutz, Wetterich, Sebastian, Fuchs, Margret, Meyer, Hanno, Siegert, Christine
Format: Conference Object
Language:unknown
Published: Bibliothek Wissenschaftspark Albert Einstein Telegrafenberg 14473 Potsdam 2016
Subjects:
Arctic
Arctic Ocean
Laptev Sea
East Siberian Sea
Andreassen
Ice
Ice Sheet
laptev
permafrost
taiga
Thermokarst
Tundra
wedge*
Siberia
Online Access:https://epic.awi.de/id/eprint/41967/
https://hdl.handle.net/10013/epic.48772
id ftawi:oai:epic.awi.de:41967
record_format openpolar
institution Open Polar
collection Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center)
op_collection_id ftawi
language unknown
description Bol’shoy Lyakhovsky, the southernmost island of the New Siberian Archipelago, holds the longest record of palaeoenvironmental history in the non-glaciated Siberian Arctic preserved in permafrost. It stretches back to ~200 kyr before present and includes prominent last interglacial thermokarst and Yedoma (Ice Complex) sections. Yet, it is unknown, whether or not the depositional history of the site is affected by the deglaciation of the northern part of the New Siberian Archipelago. Potentially, it could give insight into the break-up of the proposed MIS 6 ice sheet located on the East Siberian Sea shelf (Jakobsson et al., 2014). The lithostratigraphy of southern part of the island consists of palaeosols, floodplain and lake deposits, subaerial Yedoma and lacustrine to palustrine alas formations. Large ice wedges (partially up to several meters high and thick), segregation and pore ice record a syngenetic freezing of the Yedoma silts. Polymodal particle size distributions suggest that more than one transport mechanism drove sediment accumulation from more than one source. Recent papers conclude that the palaeoclimate record matches the general Late Quaternary climate history in northern Siberia (Andreev et al., 2011; Wetterich et al., 2011). From a multi proxy data set we focus on (i) the mineral composition (63-125 μm fraction) to determine the provenance of the deposits and to identify possible changes of transport pathways. Complementary, we use (ii) pore ice hydrochemistry as a means to track changes of the soil solution that principally reflects the site’s chemical weathering history preserved in permafrost. Presumably the two approaches complement each other, since the weathering solution should largely reflect the mineral matter composition. The heavy mineral association suggests that most of the minerals derive from the underlying bedrock (Upper Jurassic-Lower Cretaceous sandstones and Upper Cretacous granites and diorites); among others it has high amounts of ilmenite and leucoxene, epidote, pyroxenes and amphiboles, along with garnet, tourmaline, apatite, and sphene. Ratios of stable versus unstable mineral associations show that the Late Quaternary strata overlying bedrock are enriched in more stable minerals (i.e. zircon, tourmaline, ilmenite), whereas more unstable minerals (i.e. amphiboles and pyroxenes) dominate the chronostratigraphically younger Quaternary strata. A remarkably high portion of weathered mica appears in MIS4 to MIS3 deposits and raises the question upon particular hydrodynamic conditions during that time, e.g. a floodplain environment that persisted for several thousands to ten thousands of years. It may have produced various impulses of flooding with floating particles that settle out quickly on the banks of the channel and on the leeward side. Overall pore ice chemistry shows that high electrical conductivity corresponds to low ice content (<20 wt.-% of total sample weight) and vice versa; when ice content is high (>60 wt.-%) the electrical conductivity is low. When compared with the average ion composition of tundra and taiga rivers, the whole core record is enriched in the sodium- potassium load, which partially even dominates over the combined calcium-magnesium load. We preliminary conclude that the observed trends of heavy mineral and pore ice chemical variations in the Bol’shoy Lyakhovsky cores reflect short-distance material transport from weathered bedrock in the depositional area. The enrichment of mica in ice-rich deposits suggests floodplain hydrodynamics in the area during MIS 4 to MIS3. The fairly constant ionic proportions of the light soluble load in the ground ice confirm a local origin of the weathering solutes. High amounts of potassium are linked to the weathering of the granitic bedrock. Distinct concentration gradients in the downcore electrical conductivity are caused by postdepositional ionic migration from the bedrock weathering crust into the overlying Late Quaternary strata, by intensified weathering during the Last Interglacial (MIS5e), and by stable surfaces that promoted effective (e.g. cryogenic) weathering during the last Glacial (MIS4 to MIS3). Andreev, A.A., Schirrmeister, L., Tarasov, P.E., Ganopolski, A., Brovkin, V., Siegert, C., . & Hubberten, H.-W. (2011). Vegetation and climate history in the Laptev Sea region (Arctic Siberia) during Late Quaternary inferred from pollen records. Quaternary Science Reviews, 30, 2182-2199. Jakobsson, M., Andreassen, K., Bjarnadóttir, L.R., Dove, D., Dowdeswell, J.A., England, J.H., . & Larsen, N.K. (2014). Arctic Ocean glacial history. Quaternary Science Reviews, 92, 40-67. Wetterich, S., Tumskoy, V., Rudaya, N., Andreev, A.A., Opel, T., Meyer, H., . & Hüls, M. (2014). Ice Complex formation in arctic East Siberia during the MIS3 Interstadial. Quaternary Science Reviews, 84, 39- 55.
format Conference Object
author Schwamborn, Georg
Schirrmeister, Lutz
Wetterich, Sebastian
Fuchs, Margret
Meyer, Hanno
Siegert, Christine
spellingShingle Schwamborn, Georg
Schirrmeister, Lutz
Wetterich, Sebastian
Fuchs, Margret
Meyer, Hanno
Siegert, Christine
Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
author_facet Schwamborn, Georg
Schirrmeister, Lutz
Wetterich, Sebastian
Fuchs, Margret
Meyer, Hanno
Siegert, Christine
author_sort Schwamborn, Georg
title Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
title_short Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
title_full Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
title_fullStr Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
title_full_unstemmed Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores
title_sort glacial and interglacial sediment history on bol’shoy lyakhovsky, new siberian archipelago, from multiple permafrost cores
publisher Bibliothek Wissenschaftspark Albert Einstein Telegrafenberg 14473 Potsdam
publishDate 2016
url https://epic.awi.de/id/eprint/41967/
https://hdl.handle.net/10013/epic.48772
long_lat ENVELOPE(166.000,166.000,74.000,74.000)
ENVELOPE(-57.769,-57.769,-63.899,-63.899)
geographic Arctic
Arctic Ocean
Laptev Sea
East Siberian Sea
Andreassen
geographic_facet Arctic
Arctic Ocean
Laptev Sea
East Siberian Sea
Andreassen
genre Arctic
Arctic Ocean
East Siberian Sea
Ice
Ice Sheet
laptev
Laptev Sea
permafrost
taiga
Thermokarst
Tundra
wedge*
Siberia
genre_facet Arctic
Arctic Ocean
East Siberian Sea
Ice
Ice Sheet
laptev
Laptev Sea
permafrost
taiga
Thermokarst
Tundra
wedge*
Siberia
op_source EPIC3XI. International Conference On Permafrost Exploring Permafrost in a Future Earth, Potsdam, 2016-06-20-2016-06-24Potsdam, Germany, Bibliothek Wissenschaftspark Albert Einstein Telegrafenberg 14473 Potsdam
op_relation Schwamborn, G. , Schirrmeister, L. orcid:0000-0001-9455-0596 , Wetterich, S. orcid:0000-0001-9234-1192 , Fuchs, M. , Meyer, H. orcid:0000-0003-4129-4706 and Siegert, C. (2016) Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores , XI. International Conference On Permafrost Exploring Permafrost in a Future Earth, Potsdam, 20 June 2016 - 24 June 2016 . doi:10.2312/GFZ.LIS.2016.001 <https://doi.org/10.2312/GFZ.LIS.2016.001> , hdl:10013/epic.48772
op_doi https://doi.org/10.2312/GFZ.LIS.2016.001
_version_ 1766335788546523136
spelling ftawi:oai:epic.awi.de:41967 2023-05-15T15:03:56+02:00 Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores Schwamborn, Georg Schirrmeister, Lutz Wetterich, Sebastian Fuchs, Margret Meyer, Hanno Siegert, Christine 2016 https://epic.awi.de/id/eprint/41967/ https://hdl.handle.net/10013/epic.48772 unknown Bibliothek Wissenschaftspark Albert Einstein Telegrafenberg 14473 Potsdam Schwamborn, G. , Schirrmeister, L. orcid:0000-0001-9455-0596 , Wetterich, S. orcid:0000-0001-9234-1192 , Fuchs, M. , Meyer, H. orcid:0000-0003-4129-4706 and Siegert, C. (2016) Glacial and interglacial sediment history on Bol’shoy Lyakhovsky, New Siberian Archipelago, from multiple permafrost cores , XI. International Conference On Permafrost Exploring Permafrost in a Future Earth, Potsdam, 20 June 2016 - 24 June 2016 . doi:10.2312/GFZ.LIS.2016.001 <https://doi.org/10.2312/GFZ.LIS.2016.001> , hdl:10013/epic.48772 EPIC3XI. International Conference On Permafrost Exploring Permafrost in a Future Earth, Potsdam, 2016-06-20-2016-06-24Potsdam, Germany, Bibliothek Wissenschaftspark Albert Einstein Telegrafenberg 14473 Potsdam Conference notRev 2016 ftawi https://doi.org/10.2312/GFZ.LIS.2016.001 2021-12-24T15:42:00Z Bol’shoy Lyakhovsky, the southernmost island of the New Siberian Archipelago, holds the longest record of palaeoenvironmental history in the non-glaciated Siberian Arctic preserved in permafrost. It stretches back to ~200 kyr before present and includes prominent last interglacial thermokarst and Yedoma (Ice Complex) sections. Yet, it is unknown, whether or not the depositional history of the site is affected by the deglaciation of the northern part of the New Siberian Archipelago. Potentially, it could give insight into the break-up of the proposed MIS 6 ice sheet located on the East Siberian Sea shelf (Jakobsson et al., 2014). The lithostratigraphy of southern part of the island consists of palaeosols, floodplain and lake deposits, subaerial Yedoma and lacustrine to palustrine alas formations. Large ice wedges (partially up to several meters high and thick), segregation and pore ice record a syngenetic freezing of the Yedoma silts. Polymodal particle size distributions suggest that more than one transport mechanism drove sediment accumulation from more than one source. Recent papers conclude that the palaeoclimate record matches the general Late Quaternary climate history in northern Siberia (Andreev et al., 2011; Wetterich et al., 2011). From a multi proxy data set we focus on (i) the mineral composition (63-125 μm fraction) to determine the provenance of the deposits and to identify possible changes of transport pathways. Complementary, we use (ii) pore ice hydrochemistry as a means to track changes of the soil solution that principally reflects the site’s chemical weathering history preserved in permafrost. Presumably the two approaches complement each other, since the weathering solution should largely reflect the mineral matter composition. The heavy mineral association suggests that most of the minerals derive from the underlying bedrock (Upper Jurassic-Lower Cretaceous sandstones and Upper Cretacous granites and diorites); among others it has high amounts of ilmenite and leucoxene, epidote, pyroxenes and amphiboles, along with garnet, tourmaline, apatite, and sphene. Ratios of stable versus unstable mineral associations show that the Late Quaternary strata overlying bedrock are enriched in more stable minerals (i.e. zircon, tourmaline, ilmenite), whereas more unstable minerals (i.e. amphiboles and pyroxenes) dominate the chronostratigraphically younger Quaternary strata. A remarkably high portion of weathered mica appears in MIS4 to MIS3 deposits and raises the question upon particular hydrodynamic conditions during that time, e.g. a floodplain environment that persisted for several thousands to ten thousands of years. It may have produced various impulses of flooding with floating particles that settle out quickly on the banks of the channel and on the leeward side. Overall pore ice chemistry shows that high electrical conductivity corresponds to low ice content (<20 wt.-% of total sample weight) and vice versa; when ice content is high (>60 wt.-%) the electrical conductivity is low. When compared with the average ion composition of tundra and taiga rivers, the whole core record is enriched in the sodium- potassium load, which partially even dominates over the combined calcium-magnesium load. We preliminary conclude that the observed trends of heavy mineral and pore ice chemical variations in the Bol’shoy Lyakhovsky cores reflect short-distance material transport from weathered bedrock in the depositional area. The enrichment of mica in ice-rich deposits suggests floodplain hydrodynamics in the area during MIS 4 to MIS3. The fairly constant ionic proportions of the light soluble load in the ground ice confirm a local origin of the weathering solutes. High amounts of potassium are linked to the weathering of the granitic bedrock. Distinct concentration gradients in the downcore electrical conductivity are caused by postdepositional ionic migration from the bedrock weathering crust into the overlying Late Quaternary strata, by intensified weathering during the Last Interglacial (MIS5e), and by stable surfaces that promoted effective (e.g. cryogenic) weathering during the last Glacial (MIS4 to MIS3). Andreev, A.A., Schirrmeister, L., Tarasov, P.E., Ganopolski, A., Brovkin, V., Siegert, C., . & Hubberten, H.-W. (2011). Vegetation and climate history in the Laptev Sea region (Arctic Siberia) during Late Quaternary inferred from pollen records. Quaternary Science Reviews, 30, 2182-2199. Jakobsson, M., Andreassen, K., Bjarnadóttir, L.R., Dove, D., Dowdeswell, J.A., England, J.H., . & Larsen, N.K. (2014). Arctic Ocean glacial history. Quaternary Science Reviews, 92, 40-67. Wetterich, S., Tumskoy, V., Rudaya, N., Andreev, A.A., Opel, T., Meyer, H., . & Hüls, M. (2014). Ice Complex formation in arctic East Siberia during the MIS3 Interstadial. Quaternary Science Reviews, 84, 39- 55. Conference Object Arctic Arctic Ocean East Siberian Sea Ice Ice Sheet laptev Laptev Sea permafrost taiga Thermokarst Tundra wedge* Siberia Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) Arctic Arctic Ocean Laptev Sea East Siberian Sea ENVELOPE(166.000,166.000,74.000,74.000) Andreassen ENVELOPE(-57.769,-57.769,-63.899,-63.899)

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