Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment

Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment

The Southern Ocean provides a vital service by absorbing about one-sixth of humankind's annual emissions of CO<sub>2</sub>. This comes with a cost – an increase in ocean acidity that is expected to have negative impacts on ocean ecosystems. The reduced ability of phytoplankton an...

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Main Authors: T. W. Trull, A. Passmore, D. M. Davies, T. Smit, K. Berry, B. Tilbrook
Format: Article
Language:English
Published: Copernicus Publications 2018-01-01
Series:Biogeosciences
Online Access:https://www.biogeosciences.net/15/31/2018/bg-15-31-2018.pdf
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author T. W. Trull
T. W. Trull
T. W. Trull
A. Passmore
A. Passmore
D. M. Davies
D. M. Davies
T. Smit
K. Berry
K. Berry
B. Tilbrook
B. Tilbrook
spellingShingle T. W. Trull
T. W. Trull
T. W. Trull
A. Passmore
A. Passmore
D. M. Davies
D. M. Davies
T. Smit
K. Berry
K. Berry
B. Tilbrook
B. Tilbrook
Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
Biogeosciences
author_facet T. W. Trull
T. W. Trull
T. W. Trull
A. Passmore
A. Passmore
D. M. Davies
D. M. Davies
T. Smit
K. Berry
K. Berry
B. Tilbrook
B. Tilbrook
author_sort T. W. Trull
title Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
title_short Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
title_full Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
title_fullStr Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
title_full_unstemmed Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessment
title_sort distribution of planktonic biogenic carbonate organisms in the southern ocean south of australia: a baseline for ocean acidification impact assessment
publisher Copernicus Publications
series Biogeosciences
issn 1726-4170
1726-4189
publishDate 2018-01-01
description The Southern Ocean provides a vital service by absorbing about one-sixth of humankind's annual emissions of CO<sub>2</sub>. This comes with a cost – an increase in ocean acidity that is expected to have negative impacts on ocean ecosystems. The reduced ability of phytoplankton and zooplankton to precipitate carbonate shells is a clearly identified risk. The impact depends on the significance of these organisms in Southern Ocean ecosystems, but there is very little information on their abundance or distribution. To quantify their presence, we used coulometric measurement of particulate inorganic carbonate (PIC) on particles filtered from surface seawater into two size fractions: 50–1000 µm to capture foraminifera (the most important biogenic carbonate-forming zooplankton) and 1–50 µm to capture coccolithophores (the most important biogenic carbonate-forming phytoplankton). Ancillary measurements of biogenic silica (BSi) and particulate organic carbon (POC) provided context, as estimates of the biomass of diatoms (the highest biomass phytoplankton in polar waters) and total microbial biomass, respectively. Results for nine transects from Australia to Antarctica in 2008–2015 showed low levels of PIC compared to Northern Hemisphere polar waters. Coccolithophores slightly exceeded the biomass of diatoms in subantarctic waters, but their abundance decreased more than 30-fold poleward, while diatom abundances increased, so that on a molar basis PIC was only 1 % of BSi in Antarctic waters. This limited importance of coccolithophores in the Southern Ocean is further emphasized in terms of their associated POC, representing less than 1 % of total POC in Antarctic waters and less than 10 % in subantarctic waters. NASA satellite ocean-colour-based PIC estimates were in reasonable agreement with the shipboard results in subantarctic waters but greatly overestimated PIC in Antarctic waters. Contrastingly, the NASA Ocean Biogeochemical Model (NOBM) shows coccolithophores as overly restricted to subtropical and northern subantarctic waters. The cause of the strong southward decrease in PIC abundance in the Southern Ocean is not yet clear. The poleward decrease in pH is small, and while calcite saturation decreases strongly southward, it remains well above saturation ( &gt; 2). Nitrate and phosphate variations would predict a poleward increase. Temperature and competition with diatoms for limiting iron appear likely to be important. While the future trajectory of coccolithophore distributions remains uncertain, their current low abundances suggest small impacts on overall Southern Ocean pelagic ecology.
url https://www.biogeosciences.net/15/31/2018/bg-15-31-2018.pdf
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spelling doaj-a80fcd51389046188bc11e4db5c340972020-11-25T00:37:07ZengCopernicus PublicationsBiogeosciences1726-41701726-41892018-01-0115314910.5194/bg-15-31-2018Distribution of planktonic biogenic carbonate organisms in the Southern Ocean south of Australia: a baseline for ocean acidification impact assessmentT. W. Trull0T. W. Trull1T. W. Trull2A. Passmore3A. Passmore4D. M. Davies5D. M. Davies6T. Smit7K. Berry8K. Berry9B. Tilbrook10B. Tilbrook11Climate Science Centre, Oceans and Atmosphere, Commonwealth Scientific and Industrial Research Organisation, Hobart, 7001, AustraliaAntarctic Climate and Ecosystems Cooperative Research Centre, Hobart, 7001, AustraliaInstitute of Marine and Antarctic Studies, University of Tasmania, Hobart, 7001, AustraliaClimate Science Centre, Oceans and Atmosphere, Commonwealth Scientific and Industrial Research Organisation, Hobart, 7001, AustraliaAntarctic Climate and Ecosystems Cooperative Research Centre, Hobart, 7001, AustraliaClimate Science Centre, Oceans and Atmosphere, Commonwealth Scientific and Industrial Research Organisation, Hobart, 7001, AustraliaAntarctic Climate and Ecosystems Cooperative Research Centre, Hobart, 7001, AustraliaUtrecht University, Faculty of Geosciences, Utrecht, 3508, the NetherlandsClimate Science Centre, Oceans and Atmosphere, Commonwealth Scientific and Industrial Research Organisation, Hobart, 7001, AustraliaAntarctic Climate and Ecosystems Cooperative Research Centre, Hobart, 7001, AustraliaClimate Science Centre, Oceans and Atmosphere, Commonwealth Scientific and Industrial Research Organisation, Hobart, 7001, AustraliaAntarctic Climate and Ecosystems Cooperative Research Centre, Hobart, 7001, AustraliaThe Southern Ocean provides a vital service by absorbing about one-sixth of humankind's annual emissions of CO<sub>2</sub>. This comes with a cost – an increase in ocean acidity that is expected to have negative impacts on ocean ecosystems. The reduced ability of phytoplankton and zooplankton to precipitate carbonate shells is a clearly identified risk. The impact depends on the significance of these organisms in Southern Ocean ecosystems, but there is very little information on their abundance or distribution. To quantify their presence, we used coulometric measurement of particulate inorganic carbonate (PIC) on particles filtered from surface seawater into two size fractions: 50–1000 µm to capture foraminifera (the most important biogenic carbonate-forming zooplankton) and 1–50 µm to capture coccolithophores (the most important biogenic carbonate-forming phytoplankton). Ancillary measurements of biogenic silica (BSi) and particulate organic carbon (POC) provided context, as estimates of the biomass of diatoms (the highest biomass phytoplankton in polar waters) and total microbial biomass, respectively. Results for nine transects from Australia to Antarctica in 2008–2015 showed low levels of PIC compared to Northern Hemisphere polar waters. Coccolithophores slightly exceeded the biomass of diatoms in subantarctic waters, but their abundance decreased more than 30-fold poleward, while diatom abundances increased, so that on a molar basis PIC was only 1 % of BSi in Antarctic waters. This limited importance of coccolithophores in the Southern Ocean is further emphasized in terms of their associated POC, representing less than 1 % of total POC in Antarctic waters and less than 10 % in subantarctic waters. NASA satellite ocean-colour-based PIC estimates were in reasonable agreement with the shipboard results in subantarctic waters but greatly overestimated PIC in Antarctic waters. Contrastingly, the NASA Ocean Biogeochemical Model (NOBM) shows coccolithophores as overly restricted to subtropical and northern subantarctic waters. The cause of the strong southward decrease in PIC abundance in the Southern Ocean is not yet clear. The poleward decrease in pH is small, and while calcite saturation decreases strongly southward, it remains well above saturation ( &gt; 2). Nitrate and phosphate variations would predict a poleward increase. Temperature and competition with diatoms for limiting iron appear likely to be important. While the future trajectory of coccolithophore distributions remains uncertain, their current low abundances suggest small impacts on overall Southern Ocean pelagic ecology.https://www.biogeosciences.net/15/31/2018/bg-15-31-2018.pdf

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