Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4

Meltwater discharge from tidewater glaciers impacts the adjacent marine environment. Due to the global warming, tidewater glaciers are retreating and will eventually terminate on land. Yet, the mechanisms through which meltwater runoff and subglacial discharge from tidewater glaciers influence marin...

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Bibliographic Details
Main Authors: Laura Halbach, Mikko Vihtakari, Pedro Duarte, Alistair Everett, Mats A. Granskog, Haakon Hop, Hanna M. Kauko, Svein Kristiansen, Per I. Myhre, Alexey K. Pavlov, Ankit Pramanik, Agnieszka Tatarek, Tomas Torsvik, Józef M. Wiktor, Anette Wold, Angela Wulff, Harald Steen, Philipp Assmy
Format: Dataset
Language:unknown
Published: 2019
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
sediment
geology
light
ammonium
glacial meltwater
nutrients
Svalbard
Kongsfjorden
Kronebreen
glacier
Kongsfjord*
Tidewater
Online Access:https://doi.org/10.3389/fmars.2019.00254.s002
https://figshare.com/articles/Video_1_Tidewater_Glaciers_and_Bedrock_Characteristics_Control_the_Phytoplankton_Growth_Environment_in_a_Fjord_in_the_Arctic_MP4/8209019
id ftfrontimediafig:oai:figshare.com:article/8209019
record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/8209019 2023-05-15T16:22:13+02:00 Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4 Laura Halbach Mikko Vihtakari Pedro Duarte Alistair Everett Mats A. Granskog Haakon Hop Hanna M. Kauko Svein Kristiansen Per I. Myhre Alexey K. Pavlov Ankit Pramanik Agnieszka Tatarek Tomas Torsvik Józef M. Wiktor Anette Wold Angela Wulff Harald Steen Philipp Assmy 2019-05-31T11:36:10Z https://doi.org/10.3389/fmars.2019.00254.s002 https://figshare.com/articles/Video_1_Tidewater_Glaciers_and_Bedrock_Characteristics_Control_the_Phytoplankton_Growth_Environment_in_a_Fjord_in_the_Arctic_MP4/8209019 unknown doi:10.3389/fmars.2019.00254.s002 https://figshare.com/articles/Video_1_Tidewater_Glaciers_and_Bedrock_Characteristics_Control_the_Phytoplankton_Growth_Environment_in_a_Fjord_in_the_Arctic_MP4/8209019 CC BY 4.0 CC-BY Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering sediment geology light ammonium glacial meltwater nutrients Svalbard Kongsfjorden Dataset Media 2019 ftfrontimediafig https://doi.org/10.3389/fmars.2019.00254.s002 2019-06-05T22:59:02Z Meltwater discharge from tidewater glaciers impacts the adjacent marine environment. Due to the global warming, tidewater glaciers are retreating and will eventually terminate on land. Yet, the mechanisms through which meltwater runoff and subglacial discharge from tidewater glaciers influence marine primary production remain poorly understood, as data in close proximity to glacier fronts are scarce. Here, we show that subglacial meltwater discharge and bedrock characteristics of the catchments control the phytoplankton growth environment inside the fjord, based on data collected in close proximity to tidewater glacier fronts in Kongsfjorden, Svalbard from 26 to 31 July 2017. In the southern part of the inner fjord, glacial meltwater from subglacial discharge was rich in fine sediments derived from erosion of Devonian Old Red Sandstone and carbonate rock deposits, limiting light availability for phytoplankton (0.6 mg m −3 Chl a on average, range 0.2–1.9 mg m −3 ). In contrast, coarser sediments derived from gneiss and granite bedrock and lower subglacial discharge rates were associated with more favourable light conditions facilitating a local phytoplankton bloom in the northern part of the inner fjord with mean Chl a concentration of 2.8 mg m −3 (range 1.3–7.4 mg m −3 ). In the northern part, glacier meltwater was a direct source of silicic acid through weathering of the silica-rich gneiss and granite bedrock. Upwelling of the subglacial freshwater discharge plume at the Kronebreen glacier front in the southern part entrained large volumes of ambient, nutrient-rich bottom waters which led to elevated surface concentrations of ammonium, nitrate, and partly silicic acid. Total dissolved inorganic nitrogen transported to the surface with the upwelling of the subglacial discharge plume has a significant potential to enhance summer primary production in Kongsfjorden, with ammonium released from the seafloor being of particular importance. The transition from tidewater to land-terminating glaciers may, thus, reduce ... Dataset glacier Kongsfjord* Kongsfjorden Svalbard Tidewater Frontiers: Figshare Svalbard Kronebreen ENVELOPE(13.333,13.333,78.833,78.833)
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
sediment
geology
light
ammonium
glacial meltwater
nutrients
Svalbard
Kongsfjorden
spellingShingle Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
sediment
geology
light
ammonium
glacial meltwater
nutrients
Svalbard
Kongsfjorden
Laura Halbach
Mikko Vihtakari
Pedro Duarte
Alistair Everett
Mats A. Granskog
Haakon Hop
Hanna M. Kauko
Svein Kristiansen
Per I. Myhre
Alexey K. Pavlov
Ankit Pramanik
Agnieszka Tatarek
Tomas Torsvik
Józef M. Wiktor
Anette Wold
Angela Wulff
Harald Steen
Philipp Assmy
Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
topic_facet Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
sediment
geology
light
ammonium
glacial meltwater
nutrients
Svalbard
Kongsfjorden
description Meltwater discharge from tidewater glaciers impacts the adjacent marine environment. Due to the global warming, tidewater glaciers are retreating and will eventually terminate on land. Yet, the mechanisms through which meltwater runoff and subglacial discharge from tidewater glaciers influence marine primary production remain poorly understood, as data in close proximity to glacier fronts are scarce. Here, we show that subglacial meltwater discharge and bedrock characteristics of the catchments control the phytoplankton growth environment inside the fjord, based on data collected in close proximity to tidewater glacier fronts in Kongsfjorden, Svalbard from 26 to 31 July 2017. In the southern part of the inner fjord, glacial meltwater from subglacial discharge was rich in fine sediments derived from erosion of Devonian Old Red Sandstone and carbonate rock deposits, limiting light availability for phytoplankton (0.6 mg m −3 Chl a on average, range 0.2–1.9 mg m −3 ). In contrast, coarser sediments derived from gneiss and granite bedrock and lower subglacial discharge rates were associated with more favourable light conditions facilitating a local phytoplankton bloom in the northern part of the inner fjord with mean Chl a concentration of 2.8 mg m −3 (range 1.3–7.4 mg m −3 ). In the northern part, glacier meltwater was a direct source of silicic acid through weathering of the silica-rich gneiss and granite bedrock. Upwelling of the subglacial freshwater discharge plume at the Kronebreen glacier front in the southern part entrained large volumes of ambient, nutrient-rich bottom waters which led to elevated surface concentrations of ammonium, nitrate, and partly silicic acid. Total dissolved inorganic nitrogen transported to the surface with the upwelling of the subglacial discharge plume has a significant potential to enhance summer primary production in Kongsfjorden, with ammonium released from the seafloor being of particular importance. The transition from tidewater to land-terminating glaciers may, thus, reduce ...
format Dataset
author Laura Halbach
Mikko Vihtakari
Pedro Duarte
Alistair Everett
Mats A. Granskog
Haakon Hop
Hanna M. Kauko
Svein Kristiansen
Per I. Myhre
Alexey K. Pavlov
Ankit Pramanik
Agnieszka Tatarek
Tomas Torsvik
Józef M. Wiktor
Anette Wold
Angela Wulff
Harald Steen
Philipp Assmy
author_facet Laura Halbach
Mikko Vihtakari
Pedro Duarte
Alistair Everett
Mats A. Granskog
Haakon Hop
Hanna M. Kauko
Svein Kristiansen
Per I. Myhre
Alexey K. Pavlov
Ankit Pramanik
Agnieszka Tatarek
Tomas Torsvik
Józef M. Wiktor
Anette Wold
Angela Wulff
Harald Steen
Philipp Assmy
author_sort Laura Halbach
title Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
title_short Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
title_full Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
title_fullStr Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
title_full_unstemmed Video_1_Tidewater Glaciers and Bedrock Characteristics Control the Phytoplankton Growth Environment in a Fjord in the Arctic.MP4
title_sort video_1_tidewater glaciers and bedrock characteristics control the phytoplankton growth environment in a fjord in the arctic.mp4
publishDate 2019
url https://doi.org/10.3389/fmars.2019.00254.s002
https://figshare.com/articles/Video_1_Tidewater_Glaciers_and_Bedrock_Characteristics_Control_the_Phytoplankton_Growth_Environment_in_a_Fjord_in_the_Arctic_MP4/8209019
long_lat ENVELOPE(13.333,13.333,78.833,78.833)
geographic Svalbard
Kronebreen
geographic_facet Svalbard
Kronebreen
genre glacier
Kongsfjord*
Kongsfjorden
Svalbard
Tidewater
genre_facet glacier
Kongsfjord*
Kongsfjorden
Svalbard
Tidewater
op_relation doi:10.3389/fmars.2019.00254.s002
https://figshare.com/articles/Video_1_Tidewater_Glaciers_and_Bedrock_Characteristics_Control_the_Phytoplankton_Growth_Environment_in_a_Fjord_in_the_Arctic_MP4/8209019
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fmars.2019.00254.s002
_version_ 1766010181686132736

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