Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers

Greenland is by far the dominant source of glacial runoff to the oceans but the controls on the chemical and isotopic composition of this runoff are poorly known. To better constrain glacial effects on weathering processes, we have conducted elemental and lithium isotope analyses of glacial and non-...

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Published in:Earth and Planetary Science Letters
Main Authors: Wimpenny, Josh, James, Rachael H., Burton, Kevin W., Gannoun, Abdelmouhcine, Mokadem, Fatima, Gíslason, Sigurður R.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2010
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Online Access:https://eprints.soton.ac.uk/172257/
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spelling ftsouthampton:oai:eprints.soton.ac.uk:172257 2023-07-30T04:03:50+02:00 Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers Wimpenny, Josh James, Rachael H. Burton, Kevin W. Gannoun, Abdelmouhcine Mokadem, Fatima Gíslason, Sigurður R. 2010-02-20 https://eprints.soton.ac.uk/172257/ unknown Wimpenny, Josh, James, Rachael H., Burton, Kevin W., Gannoun, Abdelmouhcine, Mokadem, Fatima and Gíslason, Sigurður R. (2010) Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers. Earth and Planetary Science Letters, 290 (3-4), 427-437. (doi:10.1016/j.epsl.2009.12.042 <http://dx.doi.org/10.1016/j.epsl.2009.12.042>). Article PeerReviewed 2010 ftsouthampton https://doi.org/10.1016/j.epsl.2009.12.042 2023-07-09T21:19:26Z Greenland is by far the dominant source of glacial runoff to the oceans but the controls on the chemical and isotopic composition of this runoff are poorly known. To better constrain glacial effects on weathering processes, we have conducted elemental and lithium isotope analyses of glacial and non-glacial rivers in gneiss catchments in West Greenland. The glacial rivers have high total suspended solids (0.5 g l? 1) and low total dissolved solids (12 ?Scm? 1) relative to the non-glacial rivers, and they contain a higher proportion of dissolved Ca2+ and K+ because of subglacial, preferential, weathering of trace carbonates and biotite. The glacial rivers also have high SO42? because of the oxidation of trace sulphides under the ice. Both glacial and non-glacial rivers have high ?7Li (respectively, not, vert, similar 26‰ and not, vert, similar 30‰) relative to the rocks from which the Li is derived (not, vert, similar 8‰). Saturation state modelling suggests that this is due to the formation of Fe-oxyhydroxides in the non-glacial rivers, with preferential uptake of 6Li during inner sphere sorption of Li+ on the Fe-oxyhydroxide surface. Glacial rivers, however, are undersaturated with respect to clay minerals and Fe-oxyhydroxides. Nevertheless, leaching of suspended sediments indicates that not, vert, similar 65% of the Li in these sediments is associated with Fe-oxyhydroxide phases, and the ?7Li value of this Li is low, not, vert, similar 5‰. These results suggest that these Fe-oxyhydroxides formed under the ice, as a product of sulphide oxidation, with preferential uptake of 6Li onto the mineral surface. Solubilisation of Li from these Fe-oxyhydroxide phases is unlikely to represent a significant flux of Li to the oceans. Moreover, because the difference between the ?7Li values of glacial vs non-glacial rivers is small, glaciation has not had a significant impact on the Li isotopic composition of the riverine flux delivered to the oceans in the past, even at the height of the last deglaciation. Article in Journal/Newspaper Greenland University of Southampton: e-Prints Soton Greenland Earth and Planetary Science Letters 290 3-4 427 437
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collection University of Southampton: e-Prints Soton
op_collection_id ftsouthampton
language unknown
description Greenland is by far the dominant source of glacial runoff to the oceans but the controls on the chemical and isotopic composition of this runoff are poorly known. To better constrain glacial effects on weathering processes, we have conducted elemental and lithium isotope analyses of glacial and non-glacial rivers in gneiss catchments in West Greenland. The glacial rivers have high total suspended solids (0.5 g l? 1) and low total dissolved solids (12 ?Scm? 1) relative to the non-glacial rivers, and they contain a higher proportion of dissolved Ca2+ and K+ because of subglacial, preferential, weathering of trace carbonates and biotite. The glacial rivers also have high SO42? because of the oxidation of trace sulphides under the ice. Both glacial and non-glacial rivers have high ?7Li (respectively, not, vert, similar 26‰ and not, vert, similar 30‰) relative to the rocks from which the Li is derived (not, vert, similar 8‰). Saturation state modelling suggests that this is due to the formation of Fe-oxyhydroxides in the non-glacial rivers, with preferential uptake of 6Li during inner sphere sorption of Li+ on the Fe-oxyhydroxide surface. Glacial rivers, however, are undersaturated with respect to clay minerals and Fe-oxyhydroxides. Nevertheless, leaching of suspended sediments indicates that not, vert, similar 65% of the Li in these sediments is associated with Fe-oxyhydroxide phases, and the ?7Li value of this Li is low, not, vert, similar 5‰. These results suggest that these Fe-oxyhydroxides formed under the ice, as a product of sulphide oxidation, with preferential uptake of 6Li onto the mineral surface. Solubilisation of Li from these Fe-oxyhydroxide phases is unlikely to represent a significant flux of Li to the oceans. Moreover, because the difference between the ?7Li values of glacial vs non-glacial rivers is small, glaciation has not had a significant impact on the Li isotopic composition of the riverine flux delivered to the oceans in the past, even at the height of the last deglaciation.
format Article in Journal/Newspaper
author Wimpenny, Josh
James, Rachael H.
Burton, Kevin W.
Gannoun, Abdelmouhcine
Mokadem, Fatima
Gíslason, Sigurður R.
spellingShingle Wimpenny, Josh
James, Rachael H.
Burton, Kevin W.
Gannoun, Abdelmouhcine
Mokadem, Fatima
Gíslason, Sigurður R.
Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
author_facet Wimpenny, Josh
James, Rachael H.
Burton, Kevin W.
Gannoun, Abdelmouhcine
Mokadem, Fatima
Gíslason, Sigurður R.
author_sort Wimpenny, Josh
title Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
title_short Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
title_full Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
title_fullStr Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
title_full_unstemmed Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers
title_sort glacial effects on weathering processes: new insights from the elemental and lithium isotopic composition of west greenland rivers
publishDate 2010
url https://eprints.soton.ac.uk/172257/
geographic Greenland
geographic_facet Greenland
genre Greenland
genre_facet Greenland
op_relation Wimpenny, Josh, James, Rachael H., Burton, Kevin W., Gannoun, Abdelmouhcine, Mokadem, Fatima and Gíslason, Sigurður R. (2010) Glacial effects on weathering processes: New insights from the elemental and lithium isotopic composition of West Greenland rivers. Earth and Planetary Science Letters, 290 (3-4), 427-437. (doi:10.1016/j.epsl.2009.12.042 <http://dx.doi.org/10.1016/j.epsl.2009.12.042>).
op_doi https://doi.org/10.1016/j.epsl.2009.12.042
container_title Earth and Planetary Science Letters
container_volume 290
container_issue 3-4
container_start_page 427
op_container_end_page 437
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