Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013

Linnébreen, a 2 km2 high-arctic primarily cold-based polythermal glacier in a valley of Carboniferous sedimentary rocks and Proterozoic phyllite and schist in southwest Spitsbergen, has retreated approximately 208 m since 2004, and 1.5 km from its Little Ice Age maximum (LIAM) at around 1936. Drift...

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Bibliographic Details
Main Author: John Antonelli Whiting
Format: Dataset
Language:unknown
Published: Arctic Data Center 2013
Subjects:
EARTH SCIENCE > TERRESTRIAL HYDROSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > CRYOSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > LAND SURFACE > EROSION/SEDIMENTATION > DEGRADATION
EARTH SCIENCE > CRYOSPHERE > FROZEN GROUND > PERIGLACIAL PROCESSES
EARTH REMOTE SENSING INSTRUMENTS > PASSIVE REMOTE SENSING > POSITIONING/NAVIGATION > GPS > GPS > GLOBAL POSITIONING SYSTEM
IN SITU/LABORATORY INSTRUMENTS > PROBES > STEEL MEASURING TAPE
MANNED FIELD STATION
inlandWaters
environment
climatologyMeteorologyAtmosphere
Arctic
Svalbard
Jan Mayen
Dammed Lake
Linnévatnet
Linnébreen
Linnéelva
glacier
North Atlantic
Spitsbergen
Online Access:https://doi.org/10.18739/A24B2X431
id dataone:doi:10.18739/A24B2X431
record_format openpolar
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
topic EARTH SCIENCE > TERRESTRIAL HYDROSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > CRYOSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > LAND SURFACE > EROSION/SEDIMENTATION > DEGRADATION
EARTH SCIENCE > CRYOSPHERE > FROZEN GROUND > PERIGLACIAL PROCESSES
EARTH REMOTE SENSING INSTRUMENTS > PASSIVE REMOTE SENSING > POSITIONING/NAVIGATION > GPS > GPS > GLOBAL POSITIONING SYSTEM
IN SITU/LABORATORY INSTRUMENTS > PROBES > STEEL MEASURING TAPE
MANNED FIELD STATION
inlandWaters
environment
climatologyMeteorologyAtmosphere
spellingShingle EARTH SCIENCE > TERRESTRIAL HYDROSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > CRYOSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > LAND SURFACE > EROSION/SEDIMENTATION > DEGRADATION
EARTH SCIENCE > CRYOSPHERE > FROZEN GROUND > PERIGLACIAL PROCESSES
EARTH REMOTE SENSING INSTRUMENTS > PASSIVE REMOTE SENSING > POSITIONING/NAVIGATION > GPS > GPS > GLOBAL POSITIONING SYSTEM
IN SITU/LABORATORY INSTRUMENTS > PROBES > STEEL MEASURING TAPE
MANNED FIELD STATION
inlandWaters
environment
climatologyMeteorologyAtmosphere
John Antonelli Whiting
Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
topic_facet EARTH SCIENCE > TERRESTRIAL HYDROSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > CRYOSPHERE > GLACIERS/ICE SHEETS > GLACIERS
EARTH SCIENCE > LAND SURFACE > EROSION/SEDIMENTATION > DEGRADATION
EARTH SCIENCE > CRYOSPHERE > FROZEN GROUND > PERIGLACIAL PROCESSES
EARTH REMOTE SENSING INSTRUMENTS > PASSIVE REMOTE SENSING > POSITIONING/NAVIGATION > GPS > GPS > GLOBAL POSITIONING SYSTEM
IN SITU/LABORATORY INSTRUMENTS > PROBES > STEEL MEASURING TAPE
MANNED FIELD STATION
inlandWaters
environment
climatologyMeteorologyAtmosphere
description Linnébreen, a 2 km2 high-arctic primarily cold-based polythermal glacier in a valley of Carboniferous sedimentary rocks and Proterozoic phyllite and schist in southwest Spitsbergen, has retreated approximately 208 m since 2004, and 1.5 km from its Little Ice Age maximum (LIAM) at around 1936. Drift is continuously being reworked by meltwater as the area between the glacier and the LIAM moraine is both a sediment sink and source. Suspended sediment concentration (SSC) and particle size distribution analyses (PSD) help us to understand the current state of the ice-marginal and proglacial area. Samples were collected during the late 2012 melt season from 18 locations along supraglacial and two ice-marginal meltwater channels. These icemarginal channels converge 150 m downvalley of the glacial terminus forming the proglacial meltwater-dominated stream, Linnéelva. SSC and discharge of Linnéelva were measured from July 24 to August 8 at two proglacial locations, 0.23 and 1.22 km downvalley of the glacial terminus. Data from the ice-marginal and proglacial study locations provide clues about where meltwater is transporting sediment from the glacier or reworking ice-marginal deposits, and a broad idea of how Linnéelva is reworking sediments in the proglacial area upvalley of the LIAM moraine. Linnébreen, like many other small polythermal and cold-based glaciers in Spitsbergen, does not have moulins or many crevasses that permit meltwater flow to the glacier base; therefore, supraglacial, ice-marginal, and sub-marginal channels play a significant role in the fluvial transport of drift. Sampling of these channels took place in the late melt season when diurnal solar radiation cycles dictated discharge. On August 4 discharge of the east and west ice-marginal channels totaled 0.3 m3/s, SSC of 16 supraglacial and ice-marginal sample sites ranged from 0.01 to 0.23 g/L and averaged vii 0.12 g/L, and particle size at the same sample sites ranged from 1.01 to 22.09 μm and averaged 8.73 μm (silt). The relationships between SSC, PSD, and channel characteristics reveal ice-marginal channels to be complicated sources and sinks for glaciofluvial sediment. In many places there is a direct correlation between change in slope, SSC, and PSD. Also, samples from a supraglacial channel suggested meltwater dilution based on a decrease in SSC but no significant change in PSD. SSC and PSD suggest that the eastern ice-marginal channel was acting as a sediment sink during the late melt season. At the two proglacial sampling locations on Linnéelva discharge from July 24 to August 8 averaged 0.77 m3/s with the upper site SSC averaging 0.135 g/L, and the lower site SSC averaging 0.212 g/L. From late July to early August approximately 6.6 x 104 kg more sediment in suspension passed through the lower site than the upper site, suggesting Linnéelva is significantly eroding its banks in-between the two sample sites. However, data from the 2010 field season indicates net deposition in this same area. This shift from deposition to erosion can most likely be explained by Linnéelva downcutting through the LIAM moraine-dammed lake deposits before flowing past the lower sampling site. As Linnébreen retreats ice-marginal channels develop in areas of newly exposed basal drift, however the bulk of those sediments are most likely eroded during the high discharge events earlier in the melt season, such as the spring freshet. Data from the late melt season suggest that the bulk of material transported in suspension via the icemarginal channels originates from supraglacial and englacial debris higher on the glacial surface. These larger particles sizes are then deposited in meltwater channels downvalley as the slope and water velocity decrease. Further downvalley the SSC data from July 24 to August 8 reveal a significant amount of erosion, possibly from downcutting into lacustrine deposits. The spatial and temporal inconsistencies of stream behavior between the ice-marginal and proglacial regions within the LIAM moraine, and between the 2012 and 2010 field seasons represent difficulties in correlating environmental variation with the proglacial sediment record along Linnéelva and the glaciolacustrine record downvalley in Linnévatnet.
format Dataset
author John Antonelli Whiting
author_facet John Antonelli Whiting
author_sort John Antonelli Whiting
title Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
title_short Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
title_full Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
title_fullStr Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
title_full_unstemmed Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013
title_sort ice-marginal and proglacial fluvial characteristics of a high-arctic glacier, linnébreen, svalbard, 2013
publisher Arctic Data Center
publishDate 2013
url https://doi.org/10.18739/A24B2X431
op_coverage ATLANTIC OCEAN > NORTH ATLANTIC OCEAN > SVALBARD AND JAN MAYEN
ENVELOPE(13.86,13.988,77.98,77.949)
long_lat ENVELOPE(20.000,20.000,78.000,78.000)
ENVELOPE(-68.258,-68.258,68.496,68.496)
ENVELOPE(13.824,13.824,78.042,78.042)
ENVELOPE(13.933,13.933,77.967,77.967)
ENVELOPE(13.751,13.751,78.077,78.077)
ENVELOPE(13.86,13.988,77.98,77.949)
geographic Arctic
Svalbard
Jan Mayen
Svalbard
Dammed Lake
Linnévatnet
Linnébreen
Linnéelva
geographic_facet Arctic
Svalbard
Jan Mayen
Svalbard
Dammed Lake
Linnévatnet
Linnébreen
Linnéelva
genre Arctic
glacier
Jan Mayen
North Atlantic
Svalbard
Spitsbergen
genre_facet Arctic
glacier
Jan Mayen
North Atlantic
Svalbard
Spitsbergen
op_doi https://doi.org/10.18739/A24B2X431
_version_ 1800869937318723584
spelling dataone:doi:10.18739/A24B2X431 2024-06-03T18:46:42+00:00 Ice-Marginal and Proglacial Fluvial Characteristics of A High-Arctic Glacier, Linnébreen, Svalbard, 2013 John Antonelli Whiting ATLANTIC OCEAN > NORTH ATLANTIC OCEAN > SVALBARD AND JAN MAYEN ENVELOPE(13.86,13.988,77.98,77.949) 2013-11-11T00:00:00Z https://doi.org/10.18739/A24B2X431 unknown Arctic Data Center EARTH SCIENCE > TERRESTRIAL HYDROSPHERE > GLACIERS/ICE SHEETS > GLACIERS EARTH SCIENCE > CRYOSPHERE > GLACIERS/ICE SHEETS > GLACIERS EARTH SCIENCE > LAND SURFACE > EROSION/SEDIMENTATION > DEGRADATION EARTH SCIENCE > CRYOSPHERE > FROZEN GROUND > PERIGLACIAL PROCESSES EARTH REMOTE SENSING INSTRUMENTS > PASSIVE REMOTE SENSING > POSITIONING/NAVIGATION > GPS > GPS > GLOBAL POSITIONING SYSTEM IN SITU/LABORATORY INSTRUMENTS > PROBES > STEEL MEASURING TAPE MANNED FIELD STATION inlandWaters environment climatologyMeteorologyAtmosphere Dataset 2013 dataone:urn:node:ARCTIC https://doi.org/10.18739/A24B2X431 2024-06-03T18:11:09Z Linnébreen, a 2 km2 high-arctic primarily cold-based polythermal glacier in a valley of Carboniferous sedimentary rocks and Proterozoic phyllite and schist in southwest Spitsbergen, has retreated approximately 208 m since 2004, and 1.5 km from its Little Ice Age maximum (LIAM) at around 1936. Drift is continuously being reworked by meltwater as the area between the glacier and the LIAM moraine is both a sediment sink and source. Suspended sediment concentration (SSC) and particle size distribution analyses (PSD) help us to understand the current state of the ice-marginal and proglacial area. Samples were collected during the late 2012 melt season from 18 locations along supraglacial and two ice-marginal meltwater channels. These icemarginal channels converge 150 m downvalley of the glacial terminus forming the proglacial meltwater-dominated stream, Linnéelva. SSC and discharge of Linnéelva were measured from July 24 to August 8 at two proglacial locations, 0.23 and 1.22 km downvalley of the glacial terminus. Data from the ice-marginal and proglacial study locations provide clues about where meltwater is transporting sediment from the glacier or reworking ice-marginal deposits, and a broad idea of how Linnéelva is reworking sediments in the proglacial area upvalley of the LIAM moraine. Linnébreen, like many other small polythermal and cold-based glaciers in Spitsbergen, does not have moulins or many crevasses that permit meltwater flow to the glacier base; therefore, supraglacial, ice-marginal, and sub-marginal channels play a significant role in the fluvial transport of drift. Sampling of these channels took place in the late melt season when diurnal solar radiation cycles dictated discharge. On August 4 discharge of the east and west ice-marginal channels totaled 0.3 m3/s, SSC of 16 supraglacial and ice-marginal sample sites ranged from 0.01 to 0.23 g/L and averaged vii 0.12 g/L, and particle size at the same sample sites ranged from 1.01 to 22.09 μm and averaged 8.73 μm (silt). The relationships between SSC, PSD, and channel characteristics reveal ice-marginal channels to be complicated sources and sinks for glaciofluvial sediment. In many places there is a direct correlation between change in slope, SSC, and PSD. Also, samples from a supraglacial channel suggested meltwater dilution based on a decrease in SSC but no significant change in PSD. SSC and PSD suggest that the eastern ice-marginal channel was acting as a sediment sink during the late melt season. At the two proglacial sampling locations on Linnéelva discharge from July 24 to August 8 averaged 0.77 m3/s with the upper site SSC averaging 0.135 g/L, and the lower site SSC averaging 0.212 g/L. From late July to early August approximately 6.6 x 104 kg more sediment in suspension passed through the lower site than the upper site, suggesting Linnéelva is significantly eroding its banks in-between the two sample sites. However, data from the 2010 field season indicates net deposition in this same area. This shift from deposition to erosion can most likely be explained by Linnéelva downcutting through the LIAM moraine-dammed lake deposits before flowing past the lower sampling site. As Linnébreen retreats ice-marginal channels develop in areas of newly exposed basal drift, however the bulk of those sediments are most likely eroded during the high discharge events earlier in the melt season, such as the spring freshet. Data from the late melt season suggest that the bulk of material transported in suspension via the icemarginal channels originates from supraglacial and englacial debris higher on the glacial surface. These larger particles sizes are then deposited in meltwater channels downvalley as the slope and water velocity decrease. Further downvalley the SSC data from July 24 to August 8 reveal a significant amount of erosion, possibly from downcutting into lacustrine deposits. The spatial and temporal inconsistencies of stream behavior between the ice-marginal and proglacial regions within the LIAM moraine, and between the 2012 and 2010 field seasons represent difficulties in correlating environmental variation with the proglacial sediment record along Linnéelva and the glaciolacustrine record downvalley in Linnévatnet. Dataset Arctic glacier Jan Mayen North Atlantic Svalbard Spitsbergen Arctic Data Center (via DataONE) Arctic Svalbard Jan Mayen Svalbard ENVELOPE(20.000,20.000,78.000,78.000) Dammed Lake ENVELOPE(-68.258,-68.258,68.496,68.496) Linnévatnet ENVELOPE(13.824,13.824,78.042,78.042) Linnébreen ENVELOPE(13.933,13.933,77.967,77.967) Linnéelva ENVELOPE(13.751,13.751,78.077,78.077) ENVELOPE(13.86,13.988,77.98,77.949)

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