Changing circumpolar distributions and isoscapes of Antarctic krill: <scp>Indo‐Pacific</scp> habitat refuges counter long‐term degradation of the Atlantic sector

Yang, Guang; Atkinson, Angus; Hill, Simeon L.; Guglielmo, Letterio; Granata, Antonia; Li, Chaolun

doi:10.1002/lno.11603

Cited by 32 publications

(25 citation statements)

References 71 publications

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“…Similarly, the Brans eld region may be less responsive to changes in sea-ice habitats, supporting previous suggestions that this region may provide a pocket of resilience to climate change 21 . Similar pockets of resilience may be occurring in other regions across the circumpolar range of krill 69,70 . All these considerations are highly relevant to informing strategies for the sustainable management of the krill shery in the context of climate change.…”

Section: Discussionmentioning

confidence: 56%

Quality of Sea-ice Habitat Traversed by Antarctic Krill Larvae Influences Recruitment Success

Veytia

Bestley²,

Meiners

et al. 2022

Preprint

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Antarctic krill are a key Southern Ocean species whose success is attributed to their adaption to the extreme polar seasonality. Overwinter sea-ice presence and characteristics exert a strong control on larval survival and subsequent recruitment. Our understanding of the mechanisms through which sea ice influences survival are mainly underpinned by small-scale observations, whereas planktonic larvae may be advected over large scales. Using a state-of-the-art sea-ice model we computed Lagrangian back-trajectories to simulate larval krill advection into three distinct recruitment regions and examined modelled sea-ice habitat characteristics along trajectories. From these results we identify potential overwintering habitats and present a conceptual model for explaining regional variability in sea-ice habitat drivers of recruitment. Crucially, many of these sea-ice habitats are currently under-sampled. This work can inform future sampling efforts that will improve our understanding of climate change impacts, and potential interactions with the krill fishery.

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Section: Discussionmentioning

confidence: 56%

Quality of Sea-ice Habitat Traversed by Antarctic Krill Larvae Influences Recruitment Success

Veytia

Bestley²,

Meiners

et al. 2022

Preprint

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“…Projections suggest that changes to the distribution and abundance of both krill and its predators are likely to be apparent by the end of the current century Piñones and Fedorov, 2016;Klein et al, 2018;Tulloch et al, 2019;Veytia et al, 2020). While there is some debate over the magnitude of recent changes in krill numerical density in the Scotia Sea region (Atkinson et al, 2004(Atkinson et al, , 2019Cox et al, 2018;Cox et al, 2019;Hill et al, 2019), evidence of climate-driven changes in productivity and distribution (Huang et al, 2011;Forcada and Hoffman, 2014;Atkinson et al, 2019;McMahon et al, 2019;Yang et al, 2020), suggest that change has already occurred. Some studies suggest that climate change may bring limited benefits to some life stages.…”

Section: How Is the Es Expected To Change?mentioning

confidence: 99%

Future Risk for Southern Ocean Ecosystem Services Under Climate Change

et al. 2021

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The Southern Ocean supports ecosystem services that are important on a global scale. Climate change and human activities (tourism, fishing, and research) will affect both the demand for, and the provision of, these services into the future. Here we synthesize recent assessments of the current status and expected future climate-driven changes in Southern Ocean ecosystems and evaluate the potential consequences of these changes for the provision of ecosystem services. We explore in detail three key services (the ‘blue carbon’ pathway, the Antarctic krill fishery, and Antarctic tourism), tracing the consequences of climate change from physical drivers through biological impacts to the benefits to humans. We consider potential non-climatic drivers of change, current and future demands for the services, and the main global and regional policy frameworks that could be used to manage risks to the provision of these services in a changing climate. We also develop a formal representation of the network of interactions between the suite of potential drivers and the suite of services, providing a framework to capture the complexity of this network and its embedded feedback loops. Increased consideration of the linkages and feedbacks between drivers and ecosystem services will be required to underpin robust management responses into the future.

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“…Using data spanning 1926 to 2004, Atkinson et al (2008) estimated that 70% of the circumpolar krill stock was concentrated in the sector between 0 • and 90 • W (the southwest Atlantic); however, several independent data sources suggest that the circumpolar krill stock is now more evenly distributed with average densities in the Atlantic sector being about twice those seen in other sectors (Siegel and Watkins, 2016;Yang et al, 2020). At finer spatial scales (<1000 km), krill can be highly aggregated, with the majority of individuals occurring in large swarms (over >300 m 2 ) during summer (Murphy et al, 2004a,b;Thorpe et al, 2007;Tarling et al, 2009;Meyer et al, 2017).…”

Section: Current Distributionmentioning

confidence: 99%

“…In the intervening decade, understanding of the distribution, ecology, and response to change of these taxa has continued to advance concomitant with a greater diversity of research approaches. These advances have been facilitated in part by improved data availability as a result of new surveys and process studies (e.g., Meyer et al, 2017;Wallis, 2018;Wallis et al, 2019;Conroy et al, 2020;Yang et al, 2020), and extensive data rescue and compilation (e.g., Mackey et al, 2012;Atkinson et al, 2017;Tarling et al, 2018;Perry et al, 2019;Pinkerton et al, 2020;Takahashi et al, 2021). At the same time advances have been made in modelling across multiple taxa (e.g., Pinkerton et al, 2020) and of key species such as Antarctic krill (e.g., Constable and Kawaguchi, 2018;Veytia et al, 2020;Sylvester et al, 2021) and Thysanoessa macrura (e.g., Driscoll et al, 2015), and Salpa thompsoni (e.g., Henschke et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Status, Change, and Futures of Zooplankton in the Southern Ocean

et al. 2022

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In the Southern Ocean, several zooplankton taxonomic groups, euphausiids, copepods, salps and pteropods, are notable because of their biomass and abundance and their roles in maintaining food webs and ecosystem structure and function, including the provision of globally important ecosystem services. These groups are consumers of microbes, primary and secondary producers, and are prey for fishes, cephalopods, seabirds, and marine mammals. In providing the link between microbes, primary production, and higher trophic levels these taxa influence energy flows, biological production and biomass, biogeochemical cycles, carbon flux and food web interactions thereby modulating the structure and functioning of ecosystems. Additionally, Antarctic krill (Euphausia superba) and various fish species are harvested by international fisheries. Global and local drivers of change are expected to affect the dynamics of key zooplankton species, which may have potentially profound and wide-ranging implications for Southern Ocean ecosystems and the services they provide. Here we assess the current understanding of the dominant metazoan zooplankton within the Southern Ocean, including Antarctic krill and other key euphausiid, copepod, salp and pteropod species. We provide a systematic overview of observed and potential future responses of these taxa to a changing Southern Ocean and the functional relationships by which drivers may impact them. To support future ecosystem assessments and conservation and management strategies, we also identify priorities for Southern Ocean zooplankton research.

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Changing circumpolar distributions and isoscapes of Antarctic krill: Indo‐Pacific habitat refuges counter long‐term degradation of the Atlantic sector

Cited by 32 publications

References 71 publications

Quality of Sea-ice Habitat Traversed by Antarctic Krill Larvae Influences Recruitment Success

Quality of Sea-ice Habitat Traversed by Antarctic Krill Larvae Influences Recruitment Success

Future Risk for Southern Ocean Ecosystem Services Under Climate Change

Status, Change, and Futures of Zooplankton in the Southern Ocean

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