Biogeochemical‐Argo floats show that chlorophyll increases before carbon in the high‐latitude Southern Ocean spring bloom

Vives, Clara R.; Schallenberg, Christina; Strutton, Peter G.; Boyd, Philip W.

doi:10.1002/lol2.10322

Limnol Oceanogr Letters

2023

DOI: 10.1002/lol2.10322

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Biogeochemical‐Argo floats show that chlorophyll increases before carbon in the high‐latitude Southern Ocean spring bloom

Clara R. Vives

Christina Schallenberg

Peter G. Strutton

et al.

Abstract: In the Southern Ocean, phytoplankton blooms are an annually recurring prominent feature that play a significant role in ocean CO2 uptake. Understanding the timing of the phytoplankton bloom is necessary to provide insights into the underlying physiological drivers, for the study of ecosystem dynamics and consequent patterns in downward carbon export. Previous studies have used chlorophyll (chl) and particulate organic carbon, from either satellites or biogeochemical‐Argo (BGC‐Argo) floats, to investigate bloom… Show more

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2024

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Cited by 2 publications

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References 82 publications

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“…Similarly, zooplankton exhibit multiple phenological patterns with peaks occurring over the seasons (Calbet et al 2001;Winder and Varpe 2020). Yet, most of the plankton phenology studies focus on spring dynamics (Thackeray 2012;Yamaguchi et al 2022;Vives et al 2024) because of their substantial contribution to annual production and well-defined bloom periods (Behrenfeld and Boss 2014;Hjerne et al 2019). However, to predict temporal mismatches across trophic levels, understanding plankton phenology over the annual cycle and their response to the changing environment is critical but often understudied in marine systems.…”

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Plankton blooms over the annual cycle shape trophic interactions under climate change

Jan,

Serandour,

Walve

et al. 2024

Limnol Oceanogr Letters

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Understanding species phenology and temporal co‐occurrence across trophic levels is essential to assess anthropogenic impacts on ecological interactions. We analyzed 15 yr of monitoring data to identify trends and drivers of timing and magnitude of bloom‐forming phytoplankton and diverse zooplankton taxa in the central Baltic Sea. We show that the timings of phytoplankton blooms advance, whereas crustacean zooplankton seasonal timings remain constant. This increasing offset with the spring bloom is linked to the decline of Pseudocalanus, a key copepod sustaining pelagic fish production. The majority of copepod and cladoceran taxa, however, are co‐occurring with summer blooms. We also find new developing fall blooms, fueling secondary production later in the season. Our study highlights that response to climate change differs within and between functional groups, stressing the importance of investigating plankton phenologies over the entire annual cycle in pelagic systems.

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confidence: 99%

Plankton blooms over the annual cycle shape trophic interactions under climate change

Jan,

Serandour,

Walve

et al. 2024

Limnol Oceanogr Letters

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Changing phytoplankton phenology in the marginal ice zone west of the Antarctic Peninsula

Turner,

Dierssen,

Schofield

et al. 2024

Mar. Ecol. Prog. Ser.

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Climate change is altering global ocean phenology, the timing of annually occurring biological events. We examined the changing phenology of the phytoplankton accumulation season west of the Antarctic Peninsula to show that blooms are shifting later in the season over time in ice-associated waters. The timing of the start date and peak date of the phytoplankton accumulation season occurred later over time from 1997 to 2022 in the marginal ice zone and over the continental shelf. A divergence was seen between offshore waters and ice-associated waters, with offshore bloom timing becoming earlier, yet marginal ice zone and continental shelf bloom timing shifting later. Higher chlorophyll a (chl a) concentration in the fall season was seen in recent years, especially over the northern continental shelf. Minimal long-term trends in annual chl a occurred, likely due to the combination of later start dates in spring and higher chl a in fall. Increasing spring wind speed is the most likely mechanism for later spring start dates, leading to deeper wind mixing in a region experiencing sea ice loss. Later phytoplankton bloom timing over the marginal ice zone and continental shelf will have consequences for surface ocean carbon uptake, food web dynamics, and trophic cascades.

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Biogeochemical‐Argo floats show that chlorophyll increases before carbon in the high‐latitude Southern Ocean spring bloom

Cited by 2 publications

References 82 publications

Plankton blooms over the annual cycle shape trophic interactions under climate change

Plankton blooms over the annual cycle shape trophic interactions under climate change

Changing phytoplankton phenology in the marginal ice zone west of the Antarctic Peninsula

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