Evolution and temporal constraints of a multiphase postglacial rock slope failure

Large rock slope failures are temporal processes which act to modify the landscape after glacial retreat. The slope failure process often shows a lag time of thousands of years after deglaciation, with multiple failure events possible. While global datasets constrain this lag time from extensive map...

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Published in:Geomorphology
Main Authors: Vick, Louise Mary, Mikkelsen, Martin, Corner, Geoffrey, Kjellman, Sofia Elisabeth, Trønnes, Leif, Hormes, Anne, Allaart, Lis, Bergh, Steffen G
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2021
Subjects:
Norway
Norwegian Rock
Skredkallen
Northern Norway
Troms
Online Access:https://hdl.handle.net/10037/23862
https://doi.org/10.1016/j.geomorph.2021.108069
id ftunivtroemsoe:oai:munin.uit.no:10037/23862
record_format openpolar
spelling ftunivtroemsoe:oai:munin.uit.no:10037/23862 2023-05-15T17:43:30+02:00 Evolution and temporal constraints of a multiphase postglacial rock slope failure Vick, Louise Mary Mikkelsen, Martin Corner, Geoffrey Kjellman, Sofia Elisabeth Trønnes, Leif Hormes, Anne Allaart, Lis Bergh, Steffen G 2021-12-05 https://hdl.handle.net/10037/23862 https://doi.org/10.1016/j.geomorph.2021.108069 eng eng Elsevier Geomorphology https://doi.org/10.1016/j.geomorph.2021.108069 Vick LM, Mikkelsen, Corner, Kjellman, Trønnes, Hormes, Allaart, Bergh. Evolution and temporal constraints of a multiphase postglacial rock slope failure. Geomorphology. 2021;398 FRIDAID 1980065 doi:10.1016/j.geomorph.2021.108069 0169-555X 1872-695X https://hdl.handle.net/10037/23862 openAccess Copyright 2021 The Author(s) Journal article Tidsskriftartikkel Peer reviewed publishedVersion 2021 ftunivtroemsoe https://doi.org/10.1016/j.geomorph.2021.108069 2022-02-02T23:57:54Z Large rock slope failures are temporal processes which act to modify the landscape after glacial retreat. The slope failure process often shows a lag time of thousands of years after deglaciation, with multiple failure events possible. While global datasets constrain this lag time from extensive mapping and dating of paraglacial rock avalanches, the timeline is poorly refined in northern Norway. We present a case study of multiphase failure at Skredkallen on Vanna, one of a group of coastal islands in Troms, northern Norway. The site contains an actively deforming rock slope above a large rock avalanche deposit. The rock slope deformation (RSD) is a system of fractured and dislocated blocks up to 3 Mm 3 , and is moving slowly ~5 mm/yr downslope to the north-east. The metasedimentary rock mass contains four pervasive joint sets and a foliation, contributing to a compound structure failure mechanism. The rock mass is further weakened by foliation-parallel sheared mylonite, and the presence of a brittle fault in the immediate area, with evidence of hydrothermal fluid flow though the RSD. The rock avalanche deposit below the slope deformation is calculated to be 3Mm 3 , and extends >1 km from the source area, displaying typical mobility for north Norwegian rock avalanches onto undrained sediments. The deposits showcase exceptional lobate morphology with elongated ridge-and-furrow features. Raised shorelines predating and postdating the deposit provide temporal constraints on the deposit and an opportunity to reconstruct a relative timeline for the slope evolution. The postglacial marine limit (>14 cal. ka BP) is obscured by the deposit, while shorelines corresponding to the early Younger Dryas (12.2 cal. ka BP) and the subsequent Tapes transgression maximum (7.6–7.2 cal. ka BP) are prominent across the deposits, implying that the avalanche was emplaced between 15 and 12.2 cal. ka BP. Failure occurred during a time of immense climate instability at the boundary to the early Holocene, consistent with global reports of mountain slope failure following glacial retreat. The avalanche was emplaced into what would have been the marine environment. The anomaly between the rock avalanche source area volume(35Mm 3 ), and the rock avalanche deposit implies previous failure events, the deposits of which were either removed due to failure of the underlying marine sediments into the fjord, by retreating glacial ice or scour. The initiation of movement at the RSD may be attributed to periods of local climate changes, such as the Holocene Thermal Maximum. Cosmogenic nuclide dating is suggested as the next step to fill gaps in the slope evolution story through the mid to late Holocene. Article in Journal/Newspaper Northern Norway Troms University of Tromsø: Munin Open Research Archive Norway Norwegian Rock ENVELOPE(73.317,73.317,-53.033,-53.033) Skredkallen ENVELOPE(19.853,19.853,70.170,70.170) Geomorphology 398 108069
institution Open Polar
collection University of Tromsø: Munin Open Research Archive
op_collection_id ftunivtroemsoe
language English
description Large rock slope failures are temporal processes which act to modify the landscape after glacial retreat. The slope failure process often shows a lag time of thousands of years after deglaciation, with multiple failure events possible. While global datasets constrain this lag time from extensive mapping and dating of paraglacial rock avalanches, the timeline is poorly refined in northern Norway. We present a case study of multiphase failure at Skredkallen on Vanna, one of a group of coastal islands in Troms, northern Norway. The site contains an actively deforming rock slope above a large rock avalanche deposit. The rock slope deformation (RSD) is a system of fractured and dislocated blocks up to 3 Mm 3 , and is moving slowly ~5 mm/yr downslope to the north-east. The metasedimentary rock mass contains four pervasive joint sets and a foliation, contributing to a compound structure failure mechanism. The rock mass is further weakened by foliation-parallel sheared mylonite, and the presence of a brittle fault in the immediate area, with evidence of hydrothermal fluid flow though the RSD. The rock avalanche deposit below the slope deformation is calculated to be 3Mm 3 , and extends >1 km from the source area, displaying typical mobility for north Norwegian rock avalanches onto undrained sediments. The deposits showcase exceptional lobate morphology with elongated ridge-and-furrow features. Raised shorelines predating and postdating the deposit provide temporal constraints on the deposit and an opportunity to reconstruct a relative timeline for the slope evolution. The postglacial marine limit (>14 cal. ka BP) is obscured by the deposit, while shorelines corresponding to the early Younger Dryas (12.2 cal. ka BP) and the subsequent Tapes transgression maximum (7.6–7.2 cal. ka BP) are prominent across the deposits, implying that the avalanche was emplaced between 15 and 12.2 cal. ka BP. Failure occurred during a time of immense climate instability at the boundary to the early Holocene, consistent with global reports of mountain slope failure following glacial retreat. The avalanche was emplaced into what would have been the marine environment. The anomaly between the rock avalanche source area volume(35Mm 3 ), and the rock avalanche deposit implies previous failure events, the deposits of which were either removed due to failure of the underlying marine sediments into the fjord, by retreating glacial ice or scour. The initiation of movement at the RSD may be attributed to periods of local climate changes, such as the Holocene Thermal Maximum. Cosmogenic nuclide dating is suggested as the next step to fill gaps in the slope evolution story through the mid to late Holocene.
format Article in Journal/Newspaper
author Vick, Louise Mary
Mikkelsen, Martin
Corner, Geoffrey
Kjellman, Sofia Elisabeth
Trønnes, Leif
Hormes, Anne
Allaart, Lis
Bergh, Steffen G
spellingShingle Vick, Louise Mary
Mikkelsen, Martin
Corner, Geoffrey
Kjellman, Sofia Elisabeth
Trønnes, Leif
Hormes, Anne
Allaart, Lis
Bergh, Steffen G
Evolution and temporal constraints of a multiphase postglacial rock slope failure
author_facet Vick, Louise Mary
Mikkelsen, Martin
Corner, Geoffrey
Kjellman, Sofia Elisabeth
Trønnes, Leif
Hormes, Anne
Allaart, Lis
Bergh, Steffen G
author_sort Vick, Louise Mary
title Evolution and temporal constraints of a multiphase postglacial rock slope failure
title_short Evolution and temporal constraints of a multiphase postglacial rock slope failure
title_full Evolution and temporal constraints of a multiphase postglacial rock slope failure
title_fullStr Evolution and temporal constraints of a multiphase postglacial rock slope failure
title_full_unstemmed Evolution and temporal constraints of a multiphase postglacial rock slope failure
title_sort evolution and temporal constraints of a multiphase postglacial rock slope failure
publisher Elsevier
publishDate 2021
url https://hdl.handle.net/10037/23862
https://doi.org/10.1016/j.geomorph.2021.108069
long_lat ENVELOPE(73.317,73.317,-53.033,-53.033)
ENVELOPE(19.853,19.853,70.170,70.170)
geographic Norway
Norwegian Rock
Skredkallen
geographic_facet Norway
Norwegian Rock
Skredkallen
genre Northern Norway
Troms
genre_facet Northern Norway
Troms
op_relation Geomorphology
https://doi.org/10.1016/j.geomorph.2021.108069
Vick LM, Mikkelsen, Corner, Kjellman, Trønnes, Hormes, Allaart, Bergh. Evolution and temporal constraints of a multiphase postglacial rock slope failure. Geomorphology. 2021;398
FRIDAID 1980065
doi:10.1016/j.geomorph.2021.108069
0169-555X
1872-695X
https://hdl.handle.net/10037/23862
op_rights openAccess
Copyright 2021 The Author(s)
op_doi https://doi.org/10.1016/j.geomorph.2021.108069
container_title Geomorphology
container_volume 398
container_start_page 108069
_version_ 1766145587661504512

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