Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export

Reduction of anthropogenic CO2 emissions alone will not sufficiently restrict global warming and enable the 1.5°C goal of the Paris agreement to be met. To effectively counteract climate change, measures to actively remove carbon dioxide from the atmosphere are required. Artificial upwelling has bee...

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Published in:Frontiers in Marine Science
Main Authors: Baumann, Moritz, Taucher, Jan, Paul, Allanah J., Heinemann, Malte, Vanharanta, Mari, Bach, Lennart T., Spilling, Kristian, Ortiz, Joaquin, Arístegui Ruiz, Javier, Hernández Hernández, Nauzet, Baños Cerón, María Isabel, Riebesell, Ulf
Other Authors: #NODATA#, BU-BAS
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
251007 Oceanografía física
251002 Oceanografía química
Artificial upwelling
Export flux
Particle properties
Sinking velocity
Remineralization rate
Remineralization depth
Carbon sequestration
Mesocosm study
North Atlantic
Online Access:http://hdl.handle.net/10553/113983
https://doi.org/10.3389/fmars.2021.742142
id ftunivlaspalmas:oai:accedacris.ulpgc.es:10553/113983
record_format openpolar
spelling ftunivlaspalmas:oai:accedacris.ulpgc.es:10553/113983 2023-05-15T17:37:09+02:00 Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export Baumann, Moritz Taucher, Jan Paul, Allanah J. Heinemann, Malte Vanharanta, Mari Bach, Lennart T. Spilling, Kristian Ortiz, Joaquin Arístegui Ruiz, Javier Hernández Hernández, Nauzet Baños Cerón, María Isabel Riebesell, Ulf #NODATA# BU-BAS 2021 http://hdl.handle.net/10553/113983 https://doi.org/10.3389/fmars.2021.742142 eng eng Ocean Artificial Upwelling project (Ocean artUp, No. 695094) AQUACOSM (EU H2020-INFRAIA-project, No. 731065) Tropical and South Atlantic - climate-based marine ecosystem prediction for sustainable management PalMod Project (Nos. 01LP1505D and 01LP1919C) Frontiers in Marine Science 2296-7745 http://hdl.handle.net/10553/113983 doi:10.3389/fmars.2021.742142 2-s2.0-85118775017 WOS:000726207900001 Sí Frontiers in Marine Science [ISSN 2296-7745], n. 8, 742142, (Octubre 2021) 251007 Oceanografía física 251002 Oceanografía química Artificial upwelling Export flux Particle properties Sinking velocity Remineralization rate Remineralization depth Carbon sequestration Mesocosm study info:eu-repo/semantics/article Article 2021 ftunivlaspalmas https://doi.org/10.3389/fmars.2021.742142 2022-03-16T00:11:58Z Reduction of anthropogenic CO2 emissions alone will not sufficiently restrict global warming and enable the 1.5°C goal of the Paris agreement to be met. To effectively counteract climate change, measures to actively remove carbon dioxide from the atmosphere are required. Artificial upwelling has been proposed as one such carbon dioxide removal technique. By fueling primary productivity in the surface ocean with nutrient-rich deep water, it could potentially enhance downward fluxes of particulate organic carbon (POC) and carbon sequestration. In this study we investigated the effect of different intensities of artificial upwelling combined with two upwelling modes (recurring additions vs. one singular addition) on POC export, sinking matter stoichiometry and remineralization depth. We carried out a 39 day-long mesocosm experiment in the subtropical North Atlantic, where we fertilized oligotrophic surface waters with different amounts of deep water. The total nutrient inputs ranged from 1.6 to 11.0 μmol NO3– L–1. We found that on the one hand POC export under artificial upwelling more than doubled, and the molar C:N ratios of sinking organic matter increased from values around Redfield (6.6) to ∼8–13, which is beneficial for potential carbon dioxide removal. On the other hand, sinking matter was remineralized at faster rates and showed lower sinking velocities, which led to shallower remineralization depths. Particle properties were more favorable for deep carbon export in the recurring upwelling mode, while in the singular mode the C:N increase of sinking matter was more pronounced. In both upwelling modes roughly half of the produced organic carbon was retained in the water column until the end of the experiment. This suggests that the plankton communities were still in the process of adjustment, possibly due to the different response times of producers and consumers. There is thus a need for studies with longer experimental durations to quantify the responses of fully adjusted communities. Finally, our results revealed that artificial upwelling affects a variety of sinking particle properties, and that the intensity and mode with which it is applied control the strength of the effects. 1,558 4,912 Q1 Q1 SCIE Article in Journal/Newspaper North Atlantic Universidad de Las Palmas de Gran Canaria: Acceda Frontiers in Marine Science 8
institution Open Polar
collection Universidad de Las Palmas de Gran Canaria: Acceda
op_collection_id ftunivlaspalmas
language English
topic 251007 Oceanografía física
251002 Oceanografía química
Artificial upwelling
Export flux
Particle properties
Sinking velocity
Remineralization rate
Remineralization depth
Carbon sequestration
Mesocosm study
spellingShingle 251007 Oceanografía física
251002 Oceanografía química
Artificial upwelling
Export flux
Particle properties
Sinking velocity
Remineralization rate
Remineralization depth
Carbon sequestration
Mesocosm study
Baumann, Moritz
Taucher, Jan
Paul, Allanah J.
Heinemann, Malte
Vanharanta, Mari
Bach, Lennart T.
Spilling, Kristian
Ortiz, Joaquin
Arístegui Ruiz, Javier
Hernández Hernández, Nauzet
Baños Cerón, María Isabel
Riebesell, Ulf
Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
topic_facet 251007 Oceanografía física
251002 Oceanografía química
Artificial upwelling
Export flux
Particle properties
Sinking velocity
Remineralization rate
Remineralization depth
Carbon sequestration
Mesocosm study
description Reduction of anthropogenic CO2 emissions alone will not sufficiently restrict global warming and enable the 1.5°C goal of the Paris agreement to be met. To effectively counteract climate change, measures to actively remove carbon dioxide from the atmosphere are required. Artificial upwelling has been proposed as one such carbon dioxide removal technique. By fueling primary productivity in the surface ocean with nutrient-rich deep water, it could potentially enhance downward fluxes of particulate organic carbon (POC) and carbon sequestration. In this study we investigated the effect of different intensities of artificial upwelling combined with two upwelling modes (recurring additions vs. one singular addition) on POC export, sinking matter stoichiometry and remineralization depth. We carried out a 39 day-long mesocosm experiment in the subtropical North Atlantic, where we fertilized oligotrophic surface waters with different amounts of deep water. The total nutrient inputs ranged from 1.6 to 11.0 μmol NO3– L–1. We found that on the one hand POC export under artificial upwelling more than doubled, and the molar C:N ratios of sinking organic matter increased from values around Redfield (6.6) to ∼8–13, which is beneficial for potential carbon dioxide removal. On the other hand, sinking matter was remineralized at faster rates and showed lower sinking velocities, which led to shallower remineralization depths. Particle properties were more favorable for deep carbon export in the recurring upwelling mode, while in the singular mode the C:N increase of sinking matter was more pronounced. In both upwelling modes roughly half of the produced organic carbon was retained in the water column until the end of the experiment. This suggests that the plankton communities were still in the process of adjustment, possibly due to the different response times of producers and consumers. There is thus a need for studies with longer experimental durations to quantify the responses of fully adjusted communities. Finally, our results revealed that artificial upwelling affects a variety of sinking particle properties, and that the intensity and mode with which it is applied control the strength of the effects. 1,558 4,912 Q1 Q1 SCIE
author2 #NODATA#
BU-BAS
format Article in Journal/Newspaper
author Baumann, Moritz
Taucher, Jan
Paul, Allanah J.
Heinemann, Malte
Vanharanta, Mari
Bach, Lennart T.
Spilling, Kristian
Ortiz, Joaquin
Arístegui Ruiz, Javier
Hernández Hernández, Nauzet
Baños Cerón, María Isabel
Riebesell, Ulf
author_facet Baumann, Moritz
Taucher, Jan
Paul, Allanah J.
Heinemann, Malte
Vanharanta, Mari
Bach, Lennart T.
Spilling, Kristian
Ortiz, Joaquin
Arístegui Ruiz, Javier
Hernández Hernández, Nauzet
Baños Cerón, María Isabel
Riebesell, Ulf
author_sort Baumann, Moritz
title Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
title_short Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
title_full Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
title_fullStr Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
title_full_unstemmed Effect of Intensity and Mode of Artificial Upwelling on Particle Flux and Carbon Export
title_sort effect of intensity and mode of artificial upwelling on particle flux and carbon export
publishDate 2021
url http://hdl.handle.net/10553/113983
https://doi.org/10.3389/fmars.2021.742142
genre North Atlantic
genre_facet North Atlantic
op_source Frontiers in Marine Science [ISSN 2296-7745], n. 8, 742142, (Octubre 2021)
op_relation Ocean Artificial Upwelling project (Ocean artUp, No. 695094)
AQUACOSM (EU H2020-INFRAIA-project, No. 731065)
Tropical and South Atlantic - climate-based marine ecosystem prediction for sustainable management
PalMod Project (Nos. 01LP1505D and 01LP1919C)
Frontiers in Marine Science
2296-7745
http://hdl.handle.net/10553/113983
doi:10.3389/fmars.2021.742142
2-s2.0-85118775017
WOS:000726207900001
op_doi https://doi.org/10.3389/fmars.2021.742142
container_title Frontiers in Marine Science
container_volume 8
_version_ 1766136913173938176

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