2017
DOI: 10.1111/gcb.13890
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Biogeographic responses of the copepod Calanus glacialis to a changing Arctic marine environment

Abstract: Dramatic changes have occurred in the Arctic Ocean over the past few decades, especially in terms of sea ice loss and ocean warming. Those environmental changes may modify the planktonic ecosystem with changes from lower to upper trophic levels. This study aimed to understand how the biogeographic distribution of a crucial endemic copepod species, Calanus glacialis, may respond to both abiotic (ocean temperature) and biotic (phytoplankton prey) drivers. A copepod individual-based model coupled to an ice-ocean-… Show more

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Cited by 34 publications
(34 citation statements)
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“…Highest abundances were predicted in the Greenland Sea, Baffin Bay, and Canadian Archipelago, which have been described as C. hyperboreus distribution centers (Hirche, , ). As suggested by the IBM results, the probability of reaching the first diapausing stage is higher in shelf‐ and lower‐latitude basin areas compared to the northernmost basins (Figure ), due to higher concentration and longer duration of food supply (longer growth season) and higher temperature (faster development rate and thereby shorter development time) (Feng et al., ; Xu, Zhang, & Sun, ; Table ). For the Baffin Bay and Canadian Archipelago, highest abundances were observed in the Cape Bathurst polynya, North Water polynya, and nearby Lancaster Sound (Figure ; dataset 13, Supporting Information Table S1).…”
Section: Discussionmentioning
confidence: 83%
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“…Highest abundances were predicted in the Greenland Sea, Baffin Bay, and Canadian Archipelago, which have been described as C. hyperboreus distribution centers (Hirche, , ). As suggested by the IBM results, the probability of reaching the first diapausing stage is higher in shelf‐ and lower‐latitude basin areas compared to the northernmost basins (Figure ), due to higher concentration and longer duration of food supply (longer growth season) and higher temperature (faster development rate and thereby shorter development time) (Feng et al., ; Xu, Zhang, & Sun, ; Table ). For the Baffin Bay and Canadian Archipelago, highest abundances were observed in the Cape Bathurst polynya, North Water polynya, and nearby Lancaster Sound (Figure ; dataset 13, Supporting Information Table S1).…”
Section: Discussionmentioning
confidence: 83%
“…We used an IBM (github.com/fengzhixuan/ArcIBM/tree/trunk‐1) (Feng, Ji, Ashjian, Campbell, & Zhang, ; Feng, Ji, Campbell, Ashjian, & Zhang, ; Ji et al., ) to identify successful diapausers, that is C. hyperboreus individuals reaching halfway through stage C3. To simulate physical advection and temperature‐ and food‐dependent life cycle development, the IBM was coupled offline to BIOMAS, which provided upper 60 m depth‐averaged flow fields, temperature and food concentration, which includes phytoplankton (diatoms and flagellates), sea ice algae and microzooplankton.…”
Section: Methodsmentioning
confidence: 99%
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“…Like other large, zooplanktivorous predators, they must consistently locate energy-rich prey patches (e.g., North Atlantic right whales 4 6 ), which are in turn controlled by temperature, salinity, ice-formation and recession, phytoplankton availability, and mixing 7 , 8 . However, the predictability with which important prey such as calanoid copepods occur is likely to change in the North Atlantic and Arctic Ocean 9 14 due to rapid changes in sea surface temperature and ice conditions 15 17 .…”
Section: Introductionmentioning
confidence: 99%
“…Elevated atmospheric temperatures and the inflow of warmer waters from the Pacific and Atlantic oceans are reducing sea ice extent and thickness (Vihma 2014). The associated physical changes in the Arctic marine environment are altering the phenology of primary producers (Castellani et al 2017), their associated consumers, and subsequent higher trophic levels (Feng et al 2018). As sea surface temperatures continue to increase, southerly Atlantic and Pacific species are migrating north, ushering in novel biological interactions that have unknown consequences on existing Arctic marine food webs (Kortsch et al 2015).…”
Section: Introductionmentioning
confidence: 99%