Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone

J. R. Williams; S. L. C. Giering; C. A. Baker; K. Pabortsava; N. Briggs; H. East; B. Espinola; S. Blackbird; F. A. C. Le Moigne; M. Villa-Alfageme; A. J. Poulton; F. Carvalho; C. Pebody; K. Saw; C. M. Moore; S. A. Henson; R. Sanders; A. P. Martin

doi:10.1038/s41561-024-01602-2

Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone

J. R. Williams^*, S. L. C. Giering^*, C. A. Baker, K. Pabortsava, N. Briggs, H. East, B. Espinola, S. Blackbird, F. A. C. Le Moigne, M. Villa-Alfageme, A. J. Poulton, F. Carvalho, C. Pebody, K. Saw, C. M. Moore, S. A. Henson, R. Sanders, A. P. Martin

^*Corresponding author for this work

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Abstract

The Southern Ocean, a region highly vulnerable to climate change, plays a vital role in regulating global nutrient cycles and atmospheric CO₂ via the biological carbon pump. Diatoms, photosynthetically active plankton with dense opal skeletons, are key to this process as their exoskeletons are thought to enhance the transfer of particulate organic carbon to depth, positioning them as major vectors of carbon storage. Yet conflicting observations obscure the mechanistic link between diatoms, opal and particulate organic carbon fluxes, especially in the twilight zone where greatest flux losses occur. Here we present direct springtime flux measurements from different sectors of the subpolar Southern Ocean, demonstrating that across large areas of the subpolar twilight zone, carbon is efficiently transferred to depth, albeit not by diatoms. Rather, opal is retained near the surface ocean, indicating that processes such as diatom buoyancy regulation and grazer repackaging can negate ballast effects of diatoms’ skeletons. Our results highlight that the presence of diatoms in surface waters of the Southern Ocean’s largest biome does not guarantee their importance as vectors for efficient carbon transfer through the subpolar twilight zone. Climate change-driven shifts in phytoplankton community composition may affect biologically sequestered carbon pools less than currently predicted.

Original language	English
Pages (from-to)	72-77
Number of pages	6
Journal	Nature Geoscience
Volume	18
Issue number	1
Early online date	28 Nov 2024
DOIs	https://doi.org/10.1038/s41561-024-01602-2
Publication status	Published - Jan 2025

Keywords

Carbon cycle
Marine Biology

ASJC Scopus subject areas

General Earth and Planetary Sciences

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Williams, J. R., Giering, S. L. C., Baker, C. A., Pabortsava, K., Briggs, N., East, H., Espinola, B., Blackbird, S., Le Moigne, F. A. C., Villa-Alfageme, M., Poulton, A. J., Carvalho, F., Pebody, C., Saw, K., Moore, C. M., Henson, S. A., Sanders, R., & Martin, A. P. (2025). Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone. Nature Geoscience, 18(1), 72-77. https://doi.org/10.1038/s41561-024-01602-2

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title = "Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone",

abstract = "The Southern Ocean, a region highly vulnerable to climate change, plays a vital role in regulating global nutrient cycles and atmospheric CO2 via the biological carbon pump. Diatoms, photosynthetically active plankton with dense opal skeletons, are key to this process as their exoskeletons are thought to enhance the transfer of particulate organic carbon to depth, positioning them as major vectors of carbon storage. Yet conflicting observations obscure the mechanistic link between diatoms, opal and particulate organic carbon fluxes, especially in the twilight zone where greatest flux losses occur. Here we present direct springtime flux measurements from different sectors of the subpolar Southern Ocean, demonstrating that across large areas of the subpolar twilight zone, carbon is efficiently transferred to depth, albeit not by diatoms. Rather, opal is retained near the surface ocean, indicating that processes such as diatom buoyancy regulation and grazer repackaging can negate ballast effects of diatoms{\textquoteright} skeletons. Our results highlight that the presence of diatoms in surface waters of the Southern Ocean{\textquoteright}s largest biome does not guarantee their importance as vectors for efficient carbon transfer through the subpolar twilight zone. Climate change-driven shifts in phytoplankton community composition may affect biologically sequestered carbon pools less than currently predicted.",

keywords = "Carbon cycle, Marine Biology",

author = "Williams, {J. R.} and Giering, {S. L. C.} and Baker, {C. A.} and K. Pabortsava and N. Briggs and H. East and B. Espinola and S. Blackbird and {Le Moigne}, {F. A. C.} and M. Villa-Alfageme and Poulton, {A. J.} and F. Carvalho and C. Pebody and K. Saw and Moore, {C. M.} and Henson, {S. A.} and R. Sanders and Martin, {A. P.}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2025",

month = jan,

doi = "10.1038/s41561-024-01602-2",

language = "English",

volume = "18",

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Williams, JR, Giering, SLC, Baker, CA, Pabortsava, K, Briggs, N, East, H, Espinola, B, Blackbird, S, Le Moigne, FAC, Villa-Alfageme, M, Poulton, AJ, Carvalho, F, Pebody, C, Saw, K, Moore, CM, Henson, SA, Sanders, R & Martin, AP 2025, 'Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone', Nature Geoscience, vol. 18, no. 1, pp. 72-77. https://doi.org/10.1038/s41561-024-01602-2

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AU - Williams, J. R.

AU - Giering, S. L. C.

AU - Baker, C. A.

AU - Pabortsava, K.

AU - Briggs, N.

AU - East, H.

AU - Espinola, B.

AU - Blackbird, S.

AU - Le Moigne, F. A. C.

AU - Villa-Alfageme, M.

AU - Poulton, A. J.

AU - Carvalho, F.

AU - Pebody, C.

AU - Saw, K.

AU - Moore, C. M.

AU - Henson, S. A.

AU - Sanders, R.

AU - Martin, A. P.

PY - 2025/1

Y1 - 2025/1

N2 - The Southern Ocean, a region highly vulnerable to climate change, plays a vital role in regulating global nutrient cycles and atmospheric CO2 via the biological carbon pump. Diatoms, photosynthetically active plankton with dense opal skeletons, are key to this process as their exoskeletons are thought to enhance the transfer of particulate organic carbon to depth, positioning them as major vectors of carbon storage. Yet conflicting observations obscure the mechanistic link between diatoms, opal and particulate organic carbon fluxes, especially in the twilight zone where greatest flux losses occur. Here we present direct springtime flux measurements from different sectors of the subpolar Southern Ocean, demonstrating that across large areas of the subpolar twilight zone, carbon is efficiently transferred to depth, albeit not by diatoms. Rather, opal is retained near the surface ocean, indicating that processes such as diatom buoyancy regulation and grazer repackaging can negate ballast effects of diatoms’ skeletons. Our results highlight that the presence of diatoms in surface waters of the Southern Ocean’s largest biome does not guarantee their importance as vectors for efficient carbon transfer through the subpolar twilight zone. Climate change-driven shifts in phytoplankton community composition may affect biologically sequestered carbon pools less than currently predicted.

AB - The Southern Ocean, a region highly vulnerable to climate change, plays a vital role in regulating global nutrient cycles and atmospheric CO2 via the biological carbon pump. Diatoms, photosynthetically active plankton with dense opal skeletons, are key to this process as their exoskeletons are thought to enhance the transfer of particulate organic carbon to depth, positioning them as major vectors of carbon storage. Yet conflicting observations obscure the mechanistic link between diatoms, opal and particulate organic carbon fluxes, especially in the twilight zone where greatest flux losses occur. Here we present direct springtime flux measurements from different sectors of the subpolar Southern Ocean, demonstrating that across large areas of the subpolar twilight zone, carbon is efficiently transferred to depth, albeit not by diatoms. Rather, opal is retained near the surface ocean, indicating that processes such as diatom buoyancy regulation and grazer repackaging can negate ballast effects of diatoms’ skeletons. Our results highlight that the presence of diatoms in surface waters of the Southern Ocean’s largest biome does not guarantee their importance as vectors for efficient carbon transfer through the subpolar twilight zone. Climate change-driven shifts in phytoplankton community composition may affect biologically sequestered carbon pools less than currently predicted.

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KW - Marine Biology

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DO - 10.1038/s41561-024-01602-2

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AN - SCOPUS:85210484016

SN - 1752-0894

VL - 18

SP - 72

EP - 77

JO - Nature Geoscience

JF - Nature Geoscience

IS - 1

ER -

Inefficient transfer of diatoms through the subpolar Southern Ocean twilight zone

Abstract

Keywords

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UN SDGs

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