The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths

We analyze an optimized model of the global silicon cycle embedded in a data-assimilated steady ocean circulation. Biological uptake is modeled by conditionally restoring silicic acid in the euphotic zone to observed concentrations where the modeled concentrations exceed the observational climatolog...

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Published in:Journal of Geophysical Research: Oceans
Main Authors: Holzer, Mark, Primeau, Francois W, DeVries, Timothy, Matear, Richard
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2014
Subjects:
Physical Sciences and Mathematics
Hydrography and tracers
Numerical modeling
Nutrients and nutrient cycling
Physical and biogeochemical interactions
Antarctic
Southern Ocean
Antarc*
Online Access:http://www.escholarship.org/uc/item/4f92f1n9
id ftcdlib:qt4f92f1n9
record_format openpolar
spelling ftcdlib:qt4f92f1n9 2023-05-15T13:32:40+02:00 The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths Holzer, Mark Primeau, Francois W DeVries, Timothy Matear, Richard 313 - 331 2014-01-01 application/pdf http://www.escholarship.org/uc/item/4f92f1n9 english eng eScholarship, University of California qt4f92f1n9 http://www.escholarship.org/uc/item/4f92f1n9 Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/ CC-BY Holzer, Mark; Primeau, Francois W; DeVries, Timothy; & Matear, Richard. (2014). The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths. Journal of Geophysical Research: Oceans, 119(1), 313 - 331. doi:10.1002/2013JC009356. UC Irvine: Department of Earth System Science, UCI. Retrieved from: http://www.escholarship.org/uc/item/4f92f1n9 Physical Sciences and Mathematics Hydrography and tracers Numerical modeling Nutrients and nutrient cycling Physical and biogeochemical interactions article 2014 ftcdlib https://doi.org/10.1002/2013JC009356 2016-04-02T19:10:11Z We analyze an optimized model of the global silicon cycle embedded in a data-assimilated steady ocean circulation. Biological uptake is modeled by conditionally restoring silicic acid in the euphotic zone to observed concentrations where the modeled concentrations exceed the observational climatology. An equivalent linear model is formulated to which Green-function-based transport diagnostics are applied. We find that the models' opal export through 133 m depth is 166 ± 24 Tmol Si/yr, with the Southern Ocean (SO) providing ∼70% of this export, ∼50% of which dissolves above 2000 m depth. The global-scale gradients of the opal dissolution rate are primarily meridional, while the global-scale gradients of phosphate remineralization are primarily vertical. The mean depth of the temperature-dependent silicic-acid regeneration reaches 2300 m in the SO, compared to 600 m for phosphate remineralization. Silicic acid is stripped out of the euphotic zone far more efficiently than phosphate, with only (34 ± 5)% of the global silicic-acid inventory being preformed, compared to (61 ± 7)% for phosphate. Subantarctic and tropical waters contribute most of the ocean's regenerated silicic acid, while Antarctic waters provide most of the preformed silicic acid. About half of the global silicic-acid inventory is trapped in transport paths connecting successive SO utilizations, with silicic acid last utilized in the SO having only a (5 ± 2)% chance of being next utilized outside the SO. This trapping depletes subantarctic mode waters of silicic acid relative to phosphate, which has a (44 ± 2)% probability of escaping successive SO utilization. Article in Journal/Newspaper Antarc* Antarctic Southern Ocean University of California: eScholarship Antarctic Southern Ocean Journal of Geophysical Research: Oceans 119 1 313 331
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language English
topic Physical Sciences and Mathematics
Hydrography and tracers
Numerical modeling
Nutrients and nutrient cycling
Physical and biogeochemical interactions
spellingShingle Physical Sciences and Mathematics
Hydrography and tracers
Numerical modeling
Nutrients and nutrient cycling
Physical and biogeochemical interactions
Holzer, Mark
Primeau, Francois W
DeVries, Timothy
Matear, Richard
The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
topic_facet Physical Sciences and Mathematics
Hydrography and tracers
Numerical modeling
Nutrients and nutrient cycling
Physical and biogeochemical interactions
description We analyze an optimized model of the global silicon cycle embedded in a data-assimilated steady ocean circulation. Biological uptake is modeled by conditionally restoring silicic acid in the euphotic zone to observed concentrations where the modeled concentrations exceed the observational climatology. An equivalent linear model is formulated to which Green-function-based transport diagnostics are applied. We find that the models' opal export through 133 m depth is 166 ± 24 Tmol Si/yr, with the Southern Ocean (SO) providing ∼70% of this export, ∼50% of which dissolves above 2000 m depth. The global-scale gradients of the opal dissolution rate are primarily meridional, while the global-scale gradients of phosphate remineralization are primarily vertical. The mean depth of the temperature-dependent silicic-acid regeneration reaches 2300 m in the SO, compared to 600 m for phosphate remineralization. Silicic acid is stripped out of the euphotic zone far more efficiently than phosphate, with only (34 ± 5)% of the global silicic-acid inventory being preformed, compared to (61 ± 7)% for phosphate. Subantarctic and tropical waters contribute most of the ocean's regenerated silicic acid, while Antarctic waters provide most of the preformed silicic acid. About half of the global silicic-acid inventory is trapped in transport paths connecting successive SO utilizations, with silicic acid last utilized in the SO having only a (5 ± 2)% chance of being next utilized outside the SO. This trapping depletes subantarctic mode waters of silicic acid relative to phosphate, which has a (44 ± 2)% probability of escaping successive SO utilization.
format Article in Journal/Newspaper
author Holzer, Mark
Primeau, Francois W
DeVries, Timothy
Matear, Richard
author_facet Holzer, Mark
Primeau, Francois W
DeVries, Timothy
Matear, Richard
author_sort Holzer, Mark
title The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
title_short The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
title_full The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
title_fullStr The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
title_full_unstemmed The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
title_sort southern ocean silicon trap: data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths
publisher eScholarship, University of California
publishDate 2014
url http://www.escholarship.org/uc/item/4f92f1n9
op_coverage 313 - 331
geographic Antarctic
Southern Ocean
geographic_facet Antarctic
Southern Ocean
genre Antarc*
Antarctic
Southern Ocean
genre_facet Antarc*
Antarctic
Southern Ocean
op_source Holzer, Mark; Primeau, Francois W; DeVries, Timothy; & Matear, Richard. (2014). The Southern Ocean silicon trap: Data-constrained estimates of regenerated silicic acid, trapping efficiencies, and global transport paths. Journal of Geophysical Research: Oceans, 119(1), 313 - 331. doi:10.1002/2013JC009356. UC Irvine: Department of Earth System Science, UCI. Retrieved from: http://www.escholarship.org/uc/item/4f92f1n9
op_relation qt4f92f1n9
http://www.escholarship.org/uc/item/4f92f1n9
op_rights Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/
op_rightsnorm CC-BY
op_doi https://doi.org/10.1002/2013JC009356
container_title Journal of Geophysical Research: Oceans
container_volume 119
container_issue 1
container_start_page 313
op_container_end_page 331
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