SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND

Through physical weathering, the Greenland Ice Sheet (GIS) produces sediments which are subsequently chemically weathered in three types of watersheds: 1) deglacial watersheds that are physically disconnected from the GIS and drain local precipitation, 2) proglacial watersheds that are hydrologicall...

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Main Authors: Deuerling, Kelly M., Martin, Jonathan B., Martin, Ellen E., Scribner, Cecilia A., Collazo, Daniel F.
Format: Text
Language:unknown
Published: DigitalCommons@UNO 2015
Subjects:
Greenland
Ice Sheet
Online Access:https://digitalcommons.unomaha.edu/geoggeolfacproc/8
https://digitalcommons.unomaha.edu/context/geoggeolfacproc/article/1008/viewcontent/SEASON_1.PDF
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spelling ftuninebromaha:oai:digitalcommons.unomaha.edu:geoggeolfacproc-1008 2024-02-11T10:04:17+01:00 SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND Deuerling, Kelly M. Martin, Jonathan B. Martin, Ellen E. Scribner, Cecilia A. Collazo, Daniel F. 2015-11-01T07:00:00Z application/pdf https://digitalcommons.unomaha.edu/geoggeolfacproc/8 https://digitalcommons.unomaha.edu/context/geoggeolfacproc/article/1008/viewcontent/SEASON_1.PDF unknown DigitalCommons@UNO https://digitalcommons.unomaha.edu/geoggeolfacproc/8 https://digitalcommons.unomaha.edu/context/geoggeolfacproc/article/1008/viewcontent/SEASON_1.PDF Geography and Geology Faculty Proceedings & Presentations text 2015 ftuninebromaha 2024-01-14T17:40:48Z Through physical weathering, the Greenland Ice Sheet (GIS) produces sediments which are subsequently chemically weathered in three types of watersheds: 1) deglacial watersheds that are physically disconnected from the GIS and drain local precipitation, 2) proglacial watersheds that are hydrologically connected to the GIS, and 3) subglacial watersheds that form beneath the GIS. Chemical weathering in the glacial foreland may be important to atmospheric CO2 drawdown and oceanic fluxes of solutes, yet no holistic study exists that compares solute sources across all types of watersheds and through the melt season. Consequently, we investigated spatiotemporal changes in weathering through the 2013 ablation season from a transect of watersheds spanning the coast to the GIS in western Greenland. We sampled one proglacial (PG) watershed, from which we also assess subglacial (SG) weathering, one inland deglacial (IDG) and one coastal deglacial (CDG) watershed. A simple stoichiometric mass balance quantifies solute sources in each watershed. The principal solute source is trace carbonates in all watersheds; however, IDG has more carbonate (61 vs 36 mol%) and less silicate (3 vs 14 mol%) weathering than CDG. PG has similar carbonate (41 mol%) and silicate weathering (16 mol%) proportions to CDG, despite proximity to IDG. Weathering of biotite decreases from 12 mol% at PG to 3 mol% at CDG along an exposure age gradient, consistent with more radiogenic 87Sr/86Sr in waters at PG (0.73556) than DGC (0.71114). Carbonate weathering decreases and biotite + silicate weathering increases downstream through PG, reflecting increased weathering. Solute sources change little through time or space at IDG, but at PG, silicate weathering increases and carbonate weathering decreases as flow increases through the melt season, consistent with increased contributions of SG waters with long residence times in distributed channels. Thus, the evolution of SG through time and connections between subglacial reservoirs and main flow paths plays an ... Text Greenland Ice Sheet University of Nebraska Omaha: DigitalCommons@UNO Greenland
institution Open Polar
collection University of Nebraska Omaha: DigitalCommons@UNO
op_collection_id ftuninebromaha
language unknown
description Through physical weathering, the Greenland Ice Sheet (GIS) produces sediments which are subsequently chemically weathered in three types of watersheds: 1) deglacial watersheds that are physically disconnected from the GIS and drain local precipitation, 2) proglacial watersheds that are hydrologically connected to the GIS, and 3) subglacial watersheds that form beneath the GIS. Chemical weathering in the glacial foreland may be important to atmospheric CO2 drawdown and oceanic fluxes of solutes, yet no holistic study exists that compares solute sources across all types of watersheds and through the melt season. Consequently, we investigated spatiotemporal changes in weathering through the 2013 ablation season from a transect of watersheds spanning the coast to the GIS in western Greenland. We sampled one proglacial (PG) watershed, from which we also assess subglacial (SG) weathering, one inland deglacial (IDG) and one coastal deglacial (CDG) watershed. A simple stoichiometric mass balance quantifies solute sources in each watershed. The principal solute source is trace carbonates in all watersheds; however, IDG has more carbonate (61 vs 36 mol%) and less silicate (3 vs 14 mol%) weathering than CDG. PG has similar carbonate (41 mol%) and silicate weathering (16 mol%) proportions to CDG, despite proximity to IDG. Weathering of biotite decreases from 12 mol% at PG to 3 mol% at CDG along an exposure age gradient, consistent with more radiogenic 87Sr/86Sr in waters at PG (0.73556) than DGC (0.71114). Carbonate weathering decreases and biotite + silicate weathering increases downstream through PG, reflecting increased weathering. Solute sources change little through time or space at IDG, but at PG, silicate weathering increases and carbonate weathering decreases as flow increases through the melt season, consistent with increased contributions of SG waters with long residence times in distributed channels. Thus, the evolution of SG through time and connections between subglacial reservoirs and main flow paths plays an ...
format Text
author Deuerling, Kelly M.
Martin, Jonathan B.
Martin, Ellen E.
Scribner, Cecilia A.
Collazo, Daniel F.
spellingShingle Deuerling, Kelly M.
Martin, Jonathan B.
Martin, Ellen E.
Scribner, Cecilia A.
Collazo, Daniel F.
SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
author_facet Deuerling, Kelly M.
Martin, Jonathan B.
Martin, Ellen E.
Scribner, Cecilia A.
Collazo, Daniel F.
author_sort Deuerling, Kelly M.
title SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
title_short SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
title_full SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
title_fullStr SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
title_full_unstemmed SEASONAL EVOLUTION AND SPATIAL DISTRIBUTION OF WEATHERING IN WESTERN GREENLAND
title_sort seasonal evolution and spatial distribution of weathering in western greenland
publisher DigitalCommons@UNO
publishDate 2015
url https://digitalcommons.unomaha.edu/geoggeolfacproc/8
https://digitalcommons.unomaha.edu/context/geoggeolfacproc/article/1008/viewcontent/SEASON_1.PDF
geographic Greenland
geographic_facet Greenland
genre Greenland
Ice Sheet
genre_facet Greenland
Ice Sheet
op_source Geography and Geology Faculty Proceedings & Presentations
op_relation https://digitalcommons.unomaha.edu/geoggeolfacproc/8
https://digitalcommons.unomaha.edu/context/geoggeolfacproc/article/1008/viewcontent/SEASON_1.PDF
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