Impacts of the Changing Ocean-Sea Ice System on the Key Forage Fish Arctic Cod (Boreogadus Saida) and Subsistence Fisheries in the Western Canadian Arctic—Evaluating Linked Climate, Ecosystem and Economic (CEE) Models

Steiner, Nadja; Cheung, William W. L.; Cisneros‐Montemayor, Andrés M.; Drost, H. E.; Hayashida, Hakase; Hoover, Carie; Lam, Jen; Sou, Tessa; Sumaila, U. Rashid; Suprenand, Paul Mark; Tai, Travis C.; VanderZwaag, David

doi:10.3389/fmars.2019.00179

Cited by 57 publications

(44 citation statements)

References 129 publications

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“…With our approach we also found that the proportion of ice algae released and surviving in the pelagic system had an effect on the phytoplankton and zooplankton dynamics. Consequently, slight changes in the ice dynamic can disturb the whole structure of the present Arctic system and can modify phenologies not only of phytoplankton but also all the others species closely related of the ice algae, such as zooplankton (Werner, 1997;Søreide et al, 2010;Kohlbach et al, 2017a), fish (Kohlbach et al, 2017b;Steiner et al, 2019), or bird (Ramírez et al, 2017;Cusset et al, 2019). As an example, Polar cod (Boreogadus saida) is a central key species of the Arctic ecosystem and it is closely related to the ice algae especially during their larval development feeding on amphipods, which directly grazed on ice algae and sometimes directly feeding on ice algae itself (Gilbert et al, 1992;Kohlbach et al, 2017b).…”

Section: Resultsmentioning

confidence: 99%

On the Role of Biogeochemical Coupling Between Sympagic and Pelagic Ecosystem Compartments for Primary and Secondary Production in the Barents Sea

Benkort

Daewel

Heath

et al. 2020

Front. Environ. Sci.

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Section: Resultsmentioning

confidence: 99%

On the Role of Biogeochemical Coupling Between Sympagic and Pelagic Ecosystem Compartments for Primary and Secondary Production in the Barents Sea

Benkort

Daewel

Heath

et al. 2020

Front. Environ. Sci.

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“…The within and among individual variation in observed movement patterns of circumpolar Arctic gadids demonstrates some potential for flexibility to ecosystem change (Farrell & Franklin, 2016). However, projected initial increases in population size of southerly distributed B. saida are far outweighed by the longer projections of reduced abundance across the Arctic (Barbeaux & Hollowed, 2017;Bouchard et al, 2017;Steiner et al, 2019 (Bouchard & Fortier, 2011;Bouchard et al, 2017;Marsh & Mueter, 2020;Nahrgang et al, 2014). The physiological and habitat-specific requirements of B. saida and A. glacialis indicate that they have few viable habitats remaining to move to (Frainer et al, 2017;Vestfals et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…It is generally projected that increasing temperatures, combined with the influx of competitor and predatory sub-Arctic fishes and anthropogenic activity (e.g. pollutants from shipping and industry; Jonsson et al, 2010;fishing practices;Christiansen & George, 1995; shipping noise; Ivanova et al, 2020), will ultimately drive both A. glacialis and B. saida to move and remain for longer at higher latitudes (Astthorsson, 2015;Leo et al, 2017;Perry et al, 2005;Thorsteinson & Love, 2016) (Marsh & Mueter, 2020) specifically in relation to sea-ice concentration (Ocean Ecosystem Model: Hayashida et al, 2019;Steiner et al, 2019). Recently remodelled B. saida embryonic thermal tolerance under ocean acidification (Dahlke et al, 2018), acoustic survey abundance estimates in relation to sea ice and temperature change (Huntington et al, 2020), and backtracked biophysical models of B. saida larval recruitment in the Barents Sea show a northward retreat has begun with the potential loss of critical spawning hotspots (Huserbråten et al, 2019).…”

Section: Modelled Future Distributions and Fisheries Surveysmentioning

confidence: 99%

Cod movement ecology in a warming world: Circumpolar arctic gadids

et al. 2021

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Understanding fish movement in the Arctic is paramount during the current era of rapidly warming seas, receding sea ice and associated shifting species distributions and fishing effort. We synthesized the literature and identified key knowledge gaps on the movement ecology of Arctic cod (Boreogadus saida) and Polar/Ice cod (Arctogadus glacialis, both Gadidae) in the context of climate change. Standardized web-based English-language literature searches yielded 51 articles directly relevant and 122 indirectly relevant for the movement ecology of these species combined. Most articles were primarily relevant to B. saida (85% of total filtered articles), occurred during open water season (49/38%) with focus on distribution (32/22%), predators (30/22%), seasonal spawning/feeding movements (22/19%), sea ice association (22/26%), climate change (20/15%) and vertical movements (17/19%) with few focused on horizontal dynamics (3/0%; B. saida/A. glacialis, respectively). Disproportionate data resolution has resulted in greater predictive power of movement models for the European (29% of articles) and North American (86%) Arctic regions relative to the logistically challenging Central Arctic Ocean and Russian-Siberian Arctic shelves (both 7%). The movements of circumpolar Arctic gadids are dependent on complex dynamics that include regional currents, the longevity of ice-flows and polynyas, water stratification and coastal hydrology. Dependence on these interactive and often co-dependent processes highlights major pathways and barriers to movement and distribution at higher latitudes. Despite a recent increase in impactful research, there is a critical need for more direct research on circumpolar gadid movements to aid understanding of climate change impacts on Arctic ecosystems and fisheries.

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“…In the Canadian Arctic, warmer sea surface temperature (SST), earlier ice breakup, and their positive effects on zooplankton densities, have been linked with higher Arctic cod recruitment (Bouchard et al 2017;LeBlanc et al 2020). Hence in High Arctic seas, Arctic cod populations could benefit from climate change in the short and medium term (Bouchard et al 2017;Steiner et al 2019;LeBlanc et al 2020). However, in Low Arctic and Subarctic seas, Arctic cod recruitment and abundance are declining or expected to decline in the near future mainly in response to increasing temperatures (Drost et al 2016;CAFF 2017;Huserbråten et al 2019;Marsh and Mueter 2020).…”

Section: Introductionmentioning

confidence: 99%

West Greenland ichthyoplankton and how melting glaciers could allow Arctic cod larvae to survive extreme summer temperatures

et al. 2021

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Climate change is rapidly modifying marine fish assemblages in the Arctic. Since fish eggs and larvae have narrower thermal tolerance than nonreproductive adults, their response to increasing temperatures is likely one of the main drivers of these changes. In this study, we described ichthyoplankton assemblages in West Greenland between 62 and 73 °N, during summers 2017-2019, and investigated the relationship between sea surface temperature in the spring and summer and the survival of Arctic cod (Boreogadus saida) early life stages over the hatching season. Warm years were associated with partial recruitment failures resulting from thermal stress to the eggs and larvae hatched late in the season. Using past environmental conditions, we forecasted an imminent decline in Arctic cod recruitment in the regions of Uummannaq and Disko Bay. Observations from fjords suggested that glacial meltwater could create a subsurface thermal refuge allowing Arctic cod larvae to survive despite very high summer sea surface temperature (ca. 10°C). As the Greenland ice sheet is melting at an unprecedented speed, the mechanism underlying the ″glacial meltwater summer refuge hypothesis″ could curb some of the negative effects of ocean warming on the survival of young Arctic cod in West Greenland and other Arctic fjord systems.

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Impacts of the Changing Ocean-Sea Ice System on the Key Forage Fish Arctic Cod (Boreogadus Saida) and Subsistence Fisheries in the Western Canadian Arctic—Evaluating Linked Climate, Ecosystem and Economic (CEE) Models

Cited by 57 publications

References 129 publications

On the Role of Biogeochemical Coupling Between Sympagic and Pelagic Ecosystem Compartments for Primary and Secondary Production in the Barents Sea

On the Role of Biogeochemical Coupling Between Sympagic and Pelagic Ecosystem Compartments for Primary and Secondary Production in the Barents Sea

Cod movement ecology in a warming world: Circumpolar arctic gadids

West Greenland ichthyoplankton and how melting glaciers could allow Arctic cod larvae to survive extreme summer temperatures

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