Weddell Sea Phytoplankton Blooms Modulated by Sea Ice Variability and Polynya Formation

Berg, Lauren von; Prend, Channing J.; Campbell, Ethan; Mazloff, Matthew R.; Talley, Lynne D.; Gille, Sarah T.

doi:10.1029/2020gl087954

Cited by 24 publications

(27 citation statements)

References 77 publications

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“…Consequently, phytoplankton growth rates increase, particularly in the marginal sea ice zones (Arrigo et al, 2017;Schofield et al, 2018). Recent continuous high-resolution measurements (e.g., using autonomous floats) have also confirmed the importance of seasonal ice retreat for the timing and intensity of phytoplankton blooms (von Berg et al, 2020). Therefore, the beginning of sea ice melting in spring (September-November) linked to the increase of daylight length (Vernet et al, 2012), is the main factor that triggers phytoplankton blooms in the NAP (Varela et al, 2002;Garibotti et al, 2005b).…”

Section: Changes In the Phytoplankton Communities In The Nap Current mentioning

confidence: 93%

“…Autonomous in situ measurements will also allow for in-depth studies of the dynamics between phytoplankton and sea ice. While a few studies using floats already exist in marginal ice zones (e.g., Moreau et al, 2020;von Berg et al, 2020), further works would help reveal how phytoplankton changes with sea ice retreat at finer scales. Ocean color remote sensing, i.e., satellite-based measurements of visible light reflected off the upper ocean, will be essential toward studying the NAP ecosystem.…”

Section: Main Knowledge Gaps and Future Research Directionsmentioning

confidence: 99%

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Changes in Phytoplankton Communities Along the Northern Antarctic Peninsula: Causes, Impacts and Research Priorities

et al. 2020

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The Northern Antarctic Peninsula (NAP), located in West Antarctica, is amongst the most impacted regions by recent warming events. Its vulnerability to climate change has already led to an accumulation of severe changes along its ecosystems. This work reviews the current findings on impacts observed in phytoplankton communities occurring in the NAP, with a focus on its causes, consequences, and the potential research priorities toward an integrated comprehension of the physicalbiological coupling and climate perspective. Evident changes in phytoplankton biomass, community composition and size structure, as well as potential bottom-up impacts to the ecosystem are discussed. Surface wind, sea ice and meltwater dynamics, as key drivers of the upper layer structure, are identified as the leading factors shaping phytoplankton. Short-and long-term scenarios are suggested for phytoplankton communities in the NAP, both indicating a future increase of the importance of small flagellates at the expense of diatoms, with potential devastating impacts for the ecosystem. Five main research gaps in the current understanding of the phytoplankton response to climate change in the region are identified: (i) anthropogenic signal has yet to be disentangled from natural climate variability; (ii) the influence of small-scale ocean circulation processes on phytoplankton is poorly understood; (iii) the potential consequences to regional food webs must be clarified; (iv) the magnitude and risk of potential changes in phytoplankton composition is relatively unknown; and (v) a better understanding of phytoplankton physiological responses to changes in the environmental conditions is required. Future research directions, along with specific suggestions on how to follow them, are equally suggested. Overall, while the current

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Section: Changes In the Phytoplankton Communities In The Nap Current mentioning

confidence: 93%

Section: Main Knowledge Gaps and Future Research Directionsmentioning

confidence: 99%

Changes in Phytoplankton Communities Along the Northern Antarctic Peninsula: Causes, Impacts and Research Priorities

et al. 2020

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“…It should be noted that the detected bloom initiation may be regarded as the bloom climax if considering the bloom biomass as vertically integrated estimates instead of surface observations, and that the winter ("strict") onset of the vertically integrated bloom could occur earlier (Llort et al, 2015; see Table 1 and Supplementary Material section 2 for definitions). A recent study concentrating on biogeochemical (BGC) Argo floats providing vertical profile observations every 10-days at Maud Rise, from 2014 to 2019, indeed shows that biomass seemingly increases as early as in November with rapid increases in December (the bloom onset is not marked in their Figure 2), and that bloom climaxes in December-January (von Berg et al, 2020). Further, the detected bloom initiation in this study (i.e., climax) should correspond to favorable environmental conditions (bottom-up control) (Brody et al, 2013;Llort et al, 2015), which are discussed in the next subsections.…”

Section: Bloom Initiationmentioning

confidence: 97%

“…Furthermore, there are inherent limitations to satellite remote sensing data, such as the limited depth of the observations or array of variables provided, that can only be overcome by combining other data sources to the analysis, such as the in situ data described here. Therefore our study can contribute to new understanding, with the specific aim to characterize this area which has seldom received detailed attention besides the Maud Rise area (e.g., von Berg et al, 2020). The objectives of this paper are to describe the phytoplankton bloom phase, timing, and magnitude as observed during the autumn cruise and from the long-term ocean color remote sensing records; to explain the observed bloom patterns based on the environmental controlling factors of the bloom development, namely sea ice cover, light and MLD, and tidally induced mixing; and to delineate regional bloom regimes.…”

Section: Introductionmentioning

confidence: 99%

Phenology and Environmental Control of Phytoplankton Blooms in the Kong Håkon VII Hav in the Southern Ocean

et al. 2021

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Knowing the magnitude and timing of pelagic primary production is important for ecosystem and carbon sequestration studies, in addition to providing basic understanding of phytoplankton functioning. In this study we use data from an ecosystem cruise to Kong Håkon VII Hav, in the Atlantic sector of the Southern Ocean, in March 2019 and more than two decades of satellite-derived ocean color to study phytoplankton bloom phenology. During the cruise we observed phytoplankton blooms in different bloom phases. By correlating bloom phenology indices (i.e., bloom initiation and end) based on satellite remote sensing to the timing of changes in environmental conditions (i.e., sea ice, light, and mixed layer depth) we studied the environmental factors that seemingly drive phytoplankton blooms in the area. Our results show that blooms mainly take place in January and February, consistent with previous studies that include the area. Sea ice retreat controls the bloom initiation in particular along the coast and the western part of the study area, whereas bloom end is not primarily connected to sea ice advance. Light availability in general is not appearing to control the bloom termination, neither is nutrient availability based on the autumn cruise where we observed non-depleted macronutrient reservoirs in the surface. Instead, we surmise that zooplankton grazing plays a potentially large role to end the bloom, and thus controls its duration. The spatial correlation of the highest bloom magnitude with marked topographic features indicate that the interaction of ocean currents with sea floor topography enhances primary productivity in this area, probably by natural fertilization. Based on the bloom timing and magnitude patterns, we identified five different bloom regimes in the area. A more detailed understanding of the region will help to highlight areas with the highest relevance for the carbon cycle, the marine ecosystem and spatial management. With this gained understanding of bloom phenology, it will also be possible to study potential shifts in bloom timing and associated trophic mismatch caused by environmental changes.

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“…The seasonal succession from light to iron limitation reflects previous modeling results in the ASP (Oliver et al, 2019), as well as observations from the West Antarctic Peninsula (Arrigo et al, 2017) and the Weddell Sea (von Berg et al, 2020). We use the transition from light to iron limitation described above on a spatially averaged basis to examine differences across the domain.…”

Section: Iron-light Colimitationmentioning

confidence: 93%

Self‐Shading and Meltwater Spreading Control the Transition From Light to Iron Limitation in an Antarctic Coastal Polynya

et al. 2021

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The Southern Ocean exhibits large air-sea carbon fluxes driven by a balance between physical and biogeochemical processes. Regions where the uptake of carbon by photosynthesizing plankton exceeds physical CO 2 outgassing act as carbon sinks, reducing the quantity of carbon dioxide in the atmosphere. On a spatially integrated basis the Southern Ocean acts as an important anthropogenic carbon sink, accounting for as much as 40% of the global transfer of anthropogenic CO 2 from the atmosphere to oceans (Caldeira &

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Weddell Sea Phytoplankton Blooms Modulated by Sea Ice Variability and Polynya Formation

Cited by 24 publications

References 77 publications

Changes in Phytoplankton Communities Along the Northern Antarctic Peninsula: Causes, Impacts and Research Priorities

Changes in Phytoplankton Communities Along the Northern Antarctic Peninsula: Causes, Impacts and Research Priorities

Phenology and Environmental Control of Phytoplankton Blooms in the Kong Håkon VII Hav in the Southern Ocean

Self‐Shading and Meltwater Spreading Control the Transition From Light to Iron Limitation in an Antarctic Coastal Polynya

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