The role of mesoscale eddy stirring and microscale turbulence in sustaining biological production in the subtropical gyres
The role of mesoscale eddy stirring and microscale turbulence in sustaining biological production in the subtropical gyres
Sustaining phytoplankton primary production and organic carbon export requires the physical supply of nutrients to the sunlit ocean. In the extensive downwelling regions of the subtropical gyres, the pathways of this nutrient supply remain unclear. Vertical sinking of organic matter from the sunlit layer and its remineralization below cause net downward nutrient transfer in the upper subtropical ocean. Microscale mixing of nutrients across density surfaces and upwelling by mesoscale eddies and submesoscale fronts have been invoked to re-supply nutrients from the thermocline to the sunlit layer. However, a physical mechanism is required to replenish nutrients exported across the thermocline base and sustain a quasi-steady state upper-ocean nutrient budget on inter-annual timescales. Stirring along density surfaces by mesoscale eddies has emerged as a possible supply mechanism to close this nutrient budget. Here, we quantify the relative importance of mesoscale stirring and microscale mixing in supplying nutrients to the oligotrophic regions of the upper subtropical oceans, using global observationally based data sets for nutrients and diapycnal and isopycnal diffusivities. Mesoscale stirring dominates nutrient replenishment in the thermocline of subtropical gyres over microscale turbulence, contributing to 70%–90% of combined supply by the two processes. The stirring supply is most important along gyre flanks, where boundary currents and upwelling zones promote sharp nutrient gradients and vigorous mesoscale activity. Mesoscale fluxes provide sufficient nutrients to offset depletion in the thermocline due to upward microscale mixing into the sunlit layer. This analysis suggests that eddy stirring is significant in maintaining organic carbon export within subtropical gyres.
biological production, mesoscale eddies, mixing, nutrients, subtropical gyres, turbulence
Oglethorpe, K.
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Castro, B. Fernández
8017e93c-d5ee-4bba-b443-9c72ca512d61
Spingys, C.P.
8afecaad-9a5a-4713-949c-b47501498363
Garabato, A.C. Naveira
97c0e923-f076-4b38-b89b-938e11cea7a6
Williams, R. G.
9747da10-18ad-4de3-bcd3-7a3c8199966a
4 September 2025
Oglethorpe, K.
92980357-1c7e-4402-8a2f-099027a5f033
Castro, B. Fernández
8017e93c-d5ee-4bba-b443-9c72ca512d61
Spingys, C.P.
8afecaad-9a5a-4713-949c-b47501498363
Garabato, A.C. Naveira
97c0e923-f076-4b38-b89b-938e11cea7a6
Williams, R. G.
9747da10-18ad-4de3-bcd3-7a3c8199966a
Oglethorpe, K., Castro, B. Fernández, Spingys, C.P., Garabato, A.C. Naveira and Williams, R. G.
(2025)
The role of mesoscale eddy stirring and microscale turbulence in sustaining biological production in the subtropical gyres.
Global Biogeochemical Cycles, 39 (9), [e2024GB008180].
(doi:10.1029/2024GB008180).
Abstract
Sustaining phytoplankton primary production and organic carbon export requires the physical supply of nutrients to the sunlit ocean. In the extensive downwelling regions of the subtropical gyres, the pathways of this nutrient supply remain unclear. Vertical sinking of organic matter from the sunlit layer and its remineralization below cause net downward nutrient transfer in the upper subtropical ocean. Microscale mixing of nutrients across density surfaces and upwelling by mesoscale eddies and submesoscale fronts have been invoked to re-supply nutrients from the thermocline to the sunlit layer. However, a physical mechanism is required to replenish nutrients exported across the thermocline base and sustain a quasi-steady state upper-ocean nutrient budget on inter-annual timescales. Stirring along density surfaces by mesoscale eddies has emerged as a possible supply mechanism to close this nutrient budget. Here, we quantify the relative importance of mesoscale stirring and microscale mixing in supplying nutrients to the oligotrophic regions of the upper subtropical oceans, using global observationally based data sets for nutrients and diapycnal and isopycnal diffusivities. Mesoscale stirring dominates nutrient replenishment in the thermocline of subtropical gyres over microscale turbulence, contributing to 70%–90% of combined supply by the two processes. The stirring supply is most important along gyre flanks, where boundary currents and upwelling zones promote sharp nutrient gradients and vigorous mesoscale activity. Mesoscale fluxes provide sufficient nutrients to offset depletion in the thermocline due to upward microscale mixing into the sunlit layer. This analysis suggests that eddy stirring is significant in maintaining organic carbon export within subtropical gyres.
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Global Biogeochemical Cycles - 2025 - Oglethorpe - The Role of Mesoscale Eddy Stirring and Microscale Turbulence in
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Accepted/In Press date: 21 August 2025
e-pub ahead of print date: 4 September 2025
Published date: 4 September 2025
Keywords:
biological production, mesoscale eddies, mixing, nutrients, subtropical gyres, turbulence
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Local EPrints ID: 505814
URI: http://eprints.soton.ac.uk/id/eprint/505814
ISSN: 0886-6236
PURE UUID: e3585e44-78de-407e-99fe-f355c6d07e1c
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Date deposited: 20 Oct 2025 16:44
Last modified: 21 Oct 2025 09:25
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Author:
K. Oglethorpe
Author:
C.P. Spingys
Author:
R. G. Williams
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