Equatorial upwelling of phosphorus drives Atlantic N2 fixation and Sargassum blooms

Jonathan Jung; Nicolas N. Duprey; Alan D. Foreman; Juan Pablo D’Olivo; Carolin Pellio; Yeongjun Ryu; Erin L. Murphy; Baseerat Romshoo; Diego K. Kersting; Gabriel O. Cardoso; Tanja Wald; François Fripiat; Carlos Jimenez; Eberhard Gischler; Paolo Montagna; Carlos Alonso-Hernández; Miguel Gomez-Batista; Christina Treinen-Crespo; José Carriquiry; Maria Rosabelle Ong; Nathalie F. Goodkin; Reia Guppy; Hedy Aardema; Hans Slagter; Lena Heins; Isabella Hrabe de Angelis; Aaron L. Bieler; Maayan Yehudai; Trevor P. Noël; Kendon James; Denis Scholz; Chuanmin Hu; Brian B. Barnes; Andrea Pozzer; Christopher Pöhlker; Jos Lelieveld; Ulrich Pöschl; Hubert Vonhof; Gerald H. Haug; Ralf Schiebel; Daniel M. Sigman; Alfredo Martínez-García

doi:10.1038/s41561-025-01812-2

Equatorial upwelling of phosphorus drives Atlantic N₂ fixation and Sargassum blooms

Jonathan Jung
, Nicolas N. Duprey
, Alan D. Foreman
, Juan Pablo D’Olivo
, Carolin Pellio
, Yeongjun Ryu
, Erin L. Murphy
, Baseerat Romshoo
, Diego K. Kersting
, Gabriel O. Cardoso
, Tanja Wald
, François Fripiat
, Carlos Jimenez
, Eberhard Gischler
, Paolo Montagna
, Carlos Alonso-Hernández
, Miguel Gomez-Batista
, Christina Treinen-Crespo
, José Carriquiry
, Maria Rosabelle Ong

Nathalie F. Goodkin, Reia Guppy, Hedy Aardema, Hans Slagter, Lena Heins, Isabella Hrabe de Angelis, Aaron L. Bieler, Maayan Yehudai, Trevor P. Noël, Kendon James, Denis Scholz, Chuanmin Hu, Brian B. Barnes, Andrea Pozzer, Christopher Pöhlker, Jos Lelieveld, Ulrich Pöschl, Hubert Vonhof, Gerald H. Haug, Ralf Schiebel, Daniel M. Sigman, Alfredo Martínez-García

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

The Great Atlantic Sargassum Belt first appeared in 2011 and quickly became the largest interconnected floating biome on Earth. In recent years, Sargassum stranding events have caused substantial ecological and socio-economic impacts in coastal communities. Sargassum requires both phosphorus (P) and nitrogen (N) for growth, yet the primary sources of these nutrients fuelling the extensive Sargassum blooms remain unclear. Here we use coral-bound N isotopes to reconstruct N₂ fixation, the ultimate source of the ocean’s bioavailable N, across the Caribbean over the past 120 years. Our data indicate that changes in N₂ fixation were primarily controlled by multidecadal and interannual changes in equatorial Atlantic upwelling of ‘excess P’, that is, P in stoichiometric excess relative to fixed N. We show that the supply of excess P from equatorial upwelling and N from the N₂ fixation response can account for the majority of Sargassum variability since 2011. Sargassum dynamics are best explained by their symbiosis with N₂-fixing epiphytes, which render the macroalgae highly competitive during strong equatorial upwelling of excess P. Thus, the future of Sargassum in the tropical Atlantic will depend on how global warming affects equatorial Atlantic upwelling and the climatic modes that control it.

Original language	English (US)
Pages (from-to)	1259-1265
Number of pages	7
Journal	Nature Geoscience
Volume	18
Issue number	12
DOIs	https://doi.org/10.1038/s41561-025-01812-2
State	Published - Dec 2025

All Science Journal Classification (ASJC) codes

General Earth and Planetary Sciences

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10.1038/s41561-025-01812-2

Cite this

Jung, J., Duprey, N. N., Foreman, A. D., D’Olivo, J. P., Pellio, C., Ryu, Y., Murphy, E. L., Romshoo, B., Kersting, D. K., Cardoso, G. O., Wald, T., Fripiat, F., Jimenez, C., Gischler, E., Montagna, P., Alonso-Hernández, C., Gomez-Batista, M., Treinen-Crespo, C., Carriquiry, J., ... Martínez-García, A. (2025). Equatorial upwelling of phosphorus drives Atlantic N₂ fixation and Sargassum blooms. Nature Geoscience, 18(12), 1259-1265. https://doi.org/10.1038/s41561-025-01812-2

@article{37e3d4e4617f449fa239e320cb987867,

title = "Equatorial upwelling of phosphorus drives Atlantic N2 fixation and Sargassum blooms",

abstract = "The Great Atlantic Sargassum Belt first appeared in 2011 and quickly became the largest interconnected floating biome on Earth. In recent years, Sargassum stranding events have caused substantial ecological and socio-economic impacts in coastal communities. Sargassum requires both phosphorus (P) and nitrogen (N) for growth, yet the primary sources of these nutrients fuelling the extensive Sargassum blooms remain unclear. Here we use coral-bound N isotopes to reconstruct N2 fixation, the ultimate source of the ocean{\textquoteright}s bioavailable N, across the Caribbean over the past 120 years. Our data indicate that changes in N2 fixation were primarily controlled by multidecadal and interannual changes in equatorial Atlantic upwelling of {\textquoteleft}excess P{\textquoteright}, that is, P in stoichiometric excess relative to fixed N. We show that the supply of excess P from equatorial upwelling and N from the N2 fixation response can account for the majority of Sargassum variability since 2011. Sargassum dynamics are best explained by their symbiosis with N2-fixing epiphytes, which render the macroalgae highly competitive during strong equatorial upwelling of excess P. Thus, the future of Sargassum in the tropical Atlantic will depend on how global warming affects equatorial Atlantic upwelling and the climatic modes that control it.",

author = "Jonathan Jung and Duprey, \{Nicolas N.\} and Foreman, \{Alan D.\} and D{\textquoteright}Olivo, \{Juan Pablo\} and Carolin Pellio and Yeongjun Ryu and Murphy, \{Erin L.\} and Baseerat Romshoo and Kersting, \{Diego K.\} and Cardoso, \{Gabriel O.\} and Tanja Wald and Fran{\c c}ois Fripiat and Carlos Jimenez and Eberhard Gischler and Paolo Montagna and Carlos Alonso-Hern{\'a}ndez and Miguel Gomez-Batista and Christina Treinen-Crespo and Jos{\'e} Carriquiry and Ong, \{Maria Rosabelle\} and Goodkin, \{Nathalie F.\} and Reia Guppy and Hedy Aardema and Hans Slagter and Lena Heins and \{de Angelis\}, \{Isabella Hrabe\} and Bieler, \{Aaron L.\} and Maayan Yehudai and No{\"e}l, \{Trevor P.\} and Kendon James and Denis Scholz and Chuanmin Hu and Barnes, \{Brian B.\} and Andrea Pozzer and Christopher P{\"o}hlker and Jos Lelieveld and Ulrich P{\"o}schl and Hubert Vonhof and Haug, \{Gerald H.\} and Ralf Schiebel and Sigman, \{Daniel M.\} and Alfredo Mart{\'i}nez-Garc{\'i}a",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41561-025-01812-2",

language = "English (US)",

volume = "18",

pages = "1259--1265",

journal = "Nature Geoscience",

issn = "1752-0894",

publisher = "Nature Publishing Group",

number = "12",

}

Jung, J, Duprey, NN, Foreman, AD, D’Olivo, JP, Pellio, C, Ryu, Y, Murphy, EL, Romshoo, B, Kersting, DK, Cardoso, GO, Wald, T, Fripiat, F, Jimenez, C, Gischler, E, Montagna, P, Alonso-Hernández, C, Gomez-Batista, M, Treinen-Crespo, C, Carriquiry, J, Ong, MR, Goodkin, NF, Guppy, R, Aardema, H, Slagter, H, Heins, L, de Angelis, IH, Bieler, AL, Yehudai, M, Noël, TP, James, K, Scholz, D, Hu, C, Barnes, BB, Pozzer, A, Pöhlker, C, Lelieveld, J, Pöschl, U, Vonhof, H, Haug, GH, Schiebel, R, Sigman, DM & Martínez-García, A 2025, 'Equatorial upwelling of phosphorus drives Atlantic N₂ fixation and Sargassum blooms', Nature Geoscience, vol. 18, no. 12, pp. 1259-1265. https://doi.org/10.1038/s41561-025-01812-2

TY - JOUR

T1 - Equatorial upwelling of phosphorus drives Atlantic N2 fixation and Sargassum blooms

AU - Jung, Jonathan

AU - Duprey, Nicolas N.

AU - Foreman, Alan D.

AU - D’Olivo, Juan Pablo

AU - Pellio, Carolin

AU - Ryu, Yeongjun

AU - Murphy, Erin L.

AU - Romshoo, Baseerat

AU - Kersting, Diego K.

AU - Cardoso, Gabriel O.

AU - Wald, Tanja

AU - Fripiat, François

AU - Jimenez, Carlos

AU - Gischler, Eberhard

AU - Montagna, Paolo

AU - Alonso-Hernández, Carlos

AU - Gomez-Batista, Miguel

AU - Treinen-Crespo, Christina

AU - Carriquiry, José

AU - Ong, Maria Rosabelle

AU - Goodkin, Nathalie F.

AU - Guppy, Reia

AU - Aardema, Hedy

AU - Slagter, Hans

AU - Heins, Lena

AU - de Angelis, Isabella Hrabe

AU - Bieler, Aaron L.

AU - Yehudai, Maayan

AU - Noël, Trevor P.

AU - James, Kendon

AU - Scholz, Denis

AU - Hu, Chuanmin

AU - Barnes, Brian B.

AU - Pozzer, Andrea

AU - Pöhlker, Christopher

AU - Lelieveld, Jos

AU - Pöschl, Ulrich

AU - Vonhof, Hubert

AU - Haug, Gerald H.

AU - Schiebel, Ralf

AU - Sigman, Daniel M.

AU - Martínez-García, Alfredo

PY - 2025/12

Y1 - 2025/12

N2 - The Great Atlantic Sargassum Belt first appeared in 2011 and quickly became the largest interconnected floating biome on Earth. In recent years, Sargassum stranding events have caused substantial ecological and socio-economic impacts in coastal communities. Sargassum requires both phosphorus (P) and nitrogen (N) for growth, yet the primary sources of these nutrients fuelling the extensive Sargassum blooms remain unclear. Here we use coral-bound N isotopes to reconstruct N2 fixation, the ultimate source of the ocean’s bioavailable N, across the Caribbean over the past 120 years. Our data indicate that changes in N2 fixation were primarily controlled by multidecadal and interannual changes in equatorial Atlantic upwelling of ‘excess P’, that is, P in stoichiometric excess relative to fixed N. We show that the supply of excess P from equatorial upwelling and N from the N2 fixation response can account for the majority of Sargassum variability since 2011. Sargassum dynamics are best explained by their symbiosis with N2-fixing epiphytes, which render the macroalgae highly competitive during strong equatorial upwelling of excess P. Thus, the future of Sargassum in the tropical Atlantic will depend on how global warming affects equatorial Atlantic upwelling and the climatic modes that control it.

AB - The Great Atlantic Sargassum Belt first appeared in 2011 and quickly became the largest interconnected floating biome on Earth. In recent years, Sargassum stranding events have caused substantial ecological and socio-economic impacts in coastal communities. Sargassum requires both phosphorus (P) and nitrogen (N) for growth, yet the primary sources of these nutrients fuelling the extensive Sargassum blooms remain unclear. Here we use coral-bound N isotopes to reconstruct N2 fixation, the ultimate source of the ocean’s bioavailable N, across the Caribbean over the past 120 years. Our data indicate that changes in N2 fixation were primarily controlled by multidecadal and interannual changes in equatorial Atlantic upwelling of ‘excess P’, that is, P in stoichiometric excess relative to fixed N. We show that the supply of excess P from equatorial upwelling and N from the N2 fixation response can account for the majority of Sargassum variability since 2011. Sargassum dynamics are best explained by their symbiosis with N2-fixing epiphytes, which render the macroalgae highly competitive during strong equatorial upwelling of excess P. Thus, the future of Sargassum in the tropical Atlantic will depend on how global warming affects equatorial Atlantic upwelling and the climatic modes that control it.

UR - https://www.scopus.com/pages/publications/105021036136

UR - https://www.scopus.com/pages/publications/105021036136#tab=citedBy

U2 - 10.1038/s41561-025-01812-2

DO - 10.1038/s41561-025-01812-2

M3 - Article

AN - SCOPUS:105021036136

SN - 1752-0894

VL - 18

SP - 1259

EP - 1265

JO - Nature Geoscience

JF - Nature Geoscience

IS - 12

ER -

Equatorial upwelling of phosphorus drives Atlantic N₂ fixation and Sargassum blooms

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