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Global contribution of echinoderms to the marine carbon cycle: a re-assessment of the oceanic CaCO3 budget and the benthic compartments

Global contribution of echinoderms to the marine carbon cycle: a re-assessment of the oceanic CaCO3 budget and the benthic compartments
Global contribution of echinoderms to the marine carbon cycle: a re-assessment of the oceanic CaCO3 budget and the benthic compartments
The contribution of carbonate-producing benthic organisms to the global marine carbon budget has been overlooked, the prevailing view being that calcium carbonate (CaCO3) is predominantly produced by marine plankton. Here, we provide the first estimation of the global contribution of echinoderms to the marine carbon cycle, based on organism-level measurements from species of the five echinoderm classes. Echinoderms global CaCO3 contribution amounts to ~0.861 Pg CaCO3 yr-1 (0.102 Pg C yr-1 of inorganic carbon) as a production rate, and ~2.11 Pg CaCO3 (0.25 Pg C of inorganic carbon) as a standing stock globally. Echinoderm inorganic carbon production (0.102 Pg C yr-1) is less than the global pelagic production (0.4-1.8 Pg C yr-1), and similar to the estimates for carbonate shelves globally (0.02-0.12 Pg C yr-1). Echinoderm CaCO3 production per unit area, is ~27.01 g CaCO3 m-2 yr-1 (3.24 g C m-2 yr-1 as inorganic carbon) on a global scale for all areas, with a standing stock of ~63.34 g CaCO3 m-2 (7.60 g C m-2 as inorganic carbon), and ~7.97 g C m-2 as organic carbon. The shelf production is 77.91 g CaCO3 m-2 yr-1 (9.35 g C m-2 yr-1 as inorganic carbon) in contrast to 2.05 g CaCO3 m-2 yr-1 (0.24 g C m-2 yr-1 as inorganic carbon) for the slope on a global scale. The biogeography of the CaCO3 standing stocks of echinoderms showed strong latitudinal variability. Roughly 80% of the global CaCO3 production from echinoderms occurs between 0 and 800 meters. The shelf and upper slope contribute the most. We provide a global distribution of echinoderm populations in the context of global calcite saturation horizons, since undersaturated waters with respect to mineral phases are surfacing. This shallowing is a direct consequence of ocean acidification, and in some places it may reach the shelf and upper slope permanently. These organism-level data contribute substantially to the assessment of global carbonate inventories, which at present are poorly estimated. Additionally, it is desirable to include these benthic compartments in coupled global biogeochemical models representing the "biological pump", since at present all efforts have focused on pelagic processes, dominated by coccolithophores.

0012-9615
441-467
Lebrato, Mario
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Iglesias-Rodriguez, Debora
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Feely, Richard
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Greeley, Dana
ee2d35c1-d0f6-4d11-b3bf-94f71390accb
Jones, Daniel
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Suarez-Bosche, Nadia
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Lampitt, Richard
dfc3785c-fc7d-41fa-89ee-d0c6e27503ad
Cartes, Joan
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Green, Darryl
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Alker, Belinda
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Lebrato, Mario
0c14d20e-c641-4a61-8ba2-b6377cdf1777
Iglesias-Rodriguez, Debora
34da3d8b-ca9d-4db8-91f0-abfed4a5710f
Feely, Richard
4e22724d-a6d0-498f-a43a-1188a6bead1a
Greeley, Dana
ee2d35c1-d0f6-4d11-b3bf-94f71390accb
Jones, Daniel
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Suarez-Bosche, Nadia
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Lampitt, Richard
dfc3785c-fc7d-41fa-89ee-d0c6e27503ad
Cartes, Joan
6716e155-0f87-48fe-afed-f5c4b6e0a6f0
Green, Darryl
0d7d86c4-d674-4514-8aa6-259134dc7b57
Alker, Belinda
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Lebrato, Mario, Iglesias-Rodriguez, Debora, Feely, Richard, Greeley, Dana, Jones, Daniel, Suarez-Bosche, Nadia, Lampitt, Richard, Cartes, Joan, Green, Darryl and Alker, Belinda (2010) Global contribution of echinoderms to the marine carbon cycle: a re-assessment of the oceanic CaCO3 budget and the benthic compartments. Ecological Monographs, 80 (3), 441-467. (doi:10.1890/09-0553.1).

Record type: Article

Abstract

The contribution of carbonate-producing benthic organisms to the global marine carbon budget has been overlooked, the prevailing view being that calcium carbonate (CaCO3) is predominantly produced by marine plankton. Here, we provide the first estimation of the global contribution of echinoderms to the marine carbon cycle, based on organism-level measurements from species of the five echinoderm classes. Echinoderms global CaCO3 contribution amounts to ~0.861 Pg CaCO3 yr-1 (0.102 Pg C yr-1 of inorganic carbon) as a production rate, and ~2.11 Pg CaCO3 (0.25 Pg C of inorganic carbon) as a standing stock globally. Echinoderm inorganic carbon production (0.102 Pg C yr-1) is less than the global pelagic production (0.4-1.8 Pg C yr-1), and similar to the estimates for carbonate shelves globally (0.02-0.12 Pg C yr-1). Echinoderm CaCO3 production per unit area, is ~27.01 g CaCO3 m-2 yr-1 (3.24 g C m-2 yr-1 as inorganic carbon) on a global scale for all areas, with a standing stock of ~63.34 g CaCO3 m-2 (7.60 g C m-2 as inorganic carbon), and ~7.97 g C m-2 as organic carbon. The shelf production is 77.91 g CaCO3 m-2 yr-1 (9.35 g C m-2 yr-1 as inorganic carbon) in contrast to 2.05 g CaCO3 m-2 yr-1 (0.24 g C m-2 yr-1 as inorganic carbon) for the slope on a global scale. The biogeography of the CaCO3 standing stocks of echinoderms showed strong latitudinal variability. Roughly 80% of the global CaCO3 production from echinoderms occurs between 0 and 800 meters. The shelf and upper slope contribute the most. We provide a global distribution of echinoderm populations in the context of global calcite saturation horizons, since undersaturated waters with respect to mineral phases are surfacing. This shallowing is a direct consequence of ocean acidification, and in some places it may reach the shelf and upper slope permanently. These organism-level data contribute substantially to the assessment of global carbonate inventories, which at present are poorly estimated. Additionally, it is desirable to include these benthic compartments in coupled global biogeochemical models representing the "biological pump", since at present all efforts have focused on pelagic processes, dominated by coccolithophores.

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Published date: August 2010
Organisations: Marine Biogeochemistry

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Local EPrints ID: 71935
URI: http://eprints.soton.ac.uk/id/eprint/71935
ISSN: 0012-9615
PURE UUID: c17b2e70-c4c5-4bcd-a56c-d78af212042a

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Date deposited: 11 Jan 2010
Last modified: 13 Mar 2024 20:50

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Contributors

Author: Mario Lebrato
Author: Debora Iglesias-Rodriguez
Author: Richard Feely
Author: Dana Greeley
Author: Daniel Jones
Author: Nadia Suarez-Bosche
Author: Richard Lampitt
Author: Joan Cartes
Author: Darryl Green
Author: Belinda Alker

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