Preferential remineralization of dissolved organic phosphorus and non-Redfield DOM dynamics in the global ocean: Impacts on marine productivity, nitrogen fixation, and carbon export

Selective removal of nitrogen (N) and phosphorus (P) from the marine dissolved organic matter (DOM) pool has been reported in several regional studies. Because DOM is an important advective/mixing pathway of carbon (C) export from the ocean surface layer and its non‐Redfieldian stoichiometry would a...

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Bibliographic Details
Published in:Global biogeochemical cycles 2015-03, Vol.29 (3), p.325-340
Main Authors: Letscher, Robert T., Moore, J. Keith
Format: Article
Language:English
Subjects:
Biogeochemistry
Carbon
carbon export
Dissolved organic matter
Dissolved organic phosphorus
Gyres
marine DOM
marine N2-fixation
Nitrogen
Nitrogen fixation
non-Redfield
Phosphorus
Phytoplankton
preferential remineralization
Productivity
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Summary:Selective removal of nitrogen (N) and phosphorus (P) from the marine dissolved organic matter (DOM) pool has been reported in several regional studies. Because DOM is an important advective/mixing pathway of carbon (C) export from the ocean surface layer and its non‐Redfieldian stoichiometry would affect estimates of marine export production per unit N and P, we investigated the stoichiometry of marine DOM and its remineralization globally using a compiled DOM data set. Marine DOM is enriched in C and N compared to Redfield stoichiometry, averaging 317:39:1 and 810:48:1 for C:N:P within the degradable and total bulk pools, respectively. Dissolved organic phosphorus (DOP) is found to be preferentially remineralized about twice as rapidly with respect to the enriched C:N stoichiometry of marine DOM. Biogeochemical simulations with the Biogeochemical Elemental Cycling model using Redfield and variable DOM stoichiometry corroborate the need for non‐Redfield dynamics to match the observed DOM stoichiometry. From our model simulations, preferential DOP remineralization is found to increase the strength of the biological pump by ~9% versus the case of Redfield DOM cycling. Global net primary productivity increases ~10% including an increase in marine nitrogen fixation of ~26% when preferential DOP remineralization and direct utilization of DOP by phytoplankton are included. The largest increases in marine nitrogen fixation, net primary productivity, and carbon export are observed within the western subtropical gyres, suggesting the lateral transfer of P in the form of DOP from the productive eastern and poleward gyre margins may be important for sustaining these processes downstream in the subtropical gyres. Key Points Marine DOM and its remineralization exhibit non‐Redfield C:N:P stoichiometry Preferential remineralization of DOP increases marine N2‐fixation by 26% Marine DOC export increases global export production by 24%
ISSN:0886-6236
1944-9224
DOI:10.1002/2014GB004904