Decoding drivers of carbon flux attenuation in the oceanic biological pump

Bressac, M.; Laurenceau-Cornec, E. C.; Kennedy, F.; Santoro, A. E.; Paul, N. L.; Briggs, N.; Carvalho, F.; Boyd, P. W.

Decoding drivers of carbon flux attenuation in the oceanic biological pump

M. Bressac (), E. C. Laurenceau-Cornec, F. Kennedy, A. E. Santoro, N. L. Paul, N. Briggs, F. Carvalho and P. W. Boyd
Additional contact information
M. Bressac: Laboratoire d’Océanographie de Villefranche
E. C. Laurenceau-Cornec: University of Tasmania
F. Kennedy: University of Tasmania
A. E. Santoro: University of California
N. L. Paul: University of California
N. Briggs: National Oceanography Centre
F. Carvalho: National Oceanography Centre
P. W. Boyd: University of Tasmania

Nature, 2024, vol. 633, issue 8030, 587-593

Abstract: Abstract The biological pump supplies carbon to the oceans’ interior, driving long-term carbon sequestration and providing energy for deep-sea ecosystems1,2. Its efficiency is set by transformations of newly formed particles in the euphotic zone, followed by vertical flux attenuation via mesopelagic processes3. Depth attenuation of the particulate organic carbon (POC) flux is modulated by multiple processes involving zooplankton and/or microbes4,5. Nevertheless, it continues to be mainly parameterized using an empirically derived relationship, the ‘Martin curve’6. The derived power-law exponent is the standard metric used to compare flux attenuation patterns across oceanic provinces7,8. Here we present in situ experimental findings from C-RESPIRE9, a dual particle interceptor and incubator deployed at multiple mesopelagic depths, measuring microbially mediated POC flux attenuation. We find that across six contrasting oceanic regimes, representing a 30-fold range in POC flux, degradation by particle-attached microbes comprised 7–29 per cent of flux attenuation, implying a more influential role for zooplankton in flux attenuation. Microbial remineralization, normalized to POC flux, ranged by 20-fold across sites and depths, with the lowest rates at high POC fluxes. Vertical trends, of up to threefold changes, were linked to strong temperature gradients at low-latitude sites. In contrast, temperature played a lesser role at mid- and high-latitude sites, where vertical trends may be set jointly by particle biochemistry, fragmentation and microbial ecophysiology. This deconstruction of the Martin curve reveals the underpinning mechanisms that drive microbially mediated POC flux attenuation across oceanic provinces.

Date: 2024
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DOI: 10.1038/s41586-024-07850-x

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