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4. Changes in Arctic Ocean plankton community structure and trophic dynamics on seasonal to interannual timescales.

Author

Negrete-García, Gabriela, Luo, Jessica Y., Petrik, Colleen M., Manizza, Manfredi, and Barton, Andrew D.

Abstract

The Arctic Ocean experiences significant seasonal to interannual environmental changes, including in temperature, light, sea ice, and surface nutrient concentrations, that influence the dynamics of marine plankton populations. Here, we use a hindcast simulation (1948–2009) of size-structured Arctic Ocean plankton communities, ocean circulation, and biogeochemical cycles in order to better understand how seasonal to interannual changes in the environment influence phytoplankton physiology, plankton community structure, trophic dynamics, and fish production in the Arctic Ocean. The growth of model phytoplankton was primarily limited in winter, spring, and fall by light, but in summer, the growth of smaller and larger phytoplankton was mostly limited by temperature and nutrient availability, respectively. The dominant trophic pathway in summer was from phytoplankton to herbivorous zooplankton such that the average trophic position of model zooplankton was lower in the summer growing season compared to the rest of the year. On interannual timescales, changes in plankton community composition were strongly tied to interannual changes in bottom-up forcing by the environment. In the summer, in years with less ice and warmer temperatures, the biomass of phytoplankton and zooplankton was higher, the size–abundance relationship slopes were more negative (indicative of a phytoplankton community enriched in smaller phytoplankton), zooplankton had higher mean trophic position (indicative of greater carnivory), and potential fishery production was greater, fueled by increased mesozooplankton biomass and flux of organic matter to the benthos. The summertime shift toward greater carnivory in warmer and low-ice years was due primarily to changes in phenology, with phytoplankton and microzooplankton blooms occurring approximately 1 month earlier in these conditions and carnivorous zooplankton increasing in abundance during summer. The model provides a spatially and temporally complete overview of simulated changes in plankton communities in the Arctic Ocean occurring on seasonal to interannual timescales, and it provides insights into the mechanisms underlying these changes as well as their broader biogeochemical and ecosystem significance. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Potential impacts of climate change on agriculture and fisheries production in 72 tropical coastal communities

Author

Cinner, Joshua E., Caldwell, Iain R., Thiault, Lauric, Ben, John, Blanchard, Julia L., Coll, Marta, Diedrich, Amy, Eddy, Tyler D., Everett, Jason D., Folberth, Christian, Gascuel, Didier, Guiet, Jerome, Gurney, Georgina G., Heneghan, Ryan F., Jägermeyr, Jonas, Jiddawi, Narriman, Lahari, Rachael, Kuange, John, Liu, Wenfeng, Maury, Olivier, Müller, Christoph, Novaglio, Camilla, Palacios-Abrantes, Juliano, Petrik, Colleen M., Rabearisoa, Ando, Tittensor, Derek P., Wamukota, Andrew, and Pollnac, Richard

Published
2022
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6. Disentangling diverse responses to climate change among global marine ecosystem models

Author

Heneghan, Ryan F., Galbraith, Eric, Blanchard, Julia L., Harrison, Cheryl, Barrier, Nicolas, Bulman, Catherine, Cheung, William, Coll, Marta, Eddy, Tyler D., Erauskin-Extramiana, Maite, Everett, Jason D., Fernandes-Salvador, Jose A., Gascuel, Didier, Guiet, Jerome, Maury, Olivier, Palacios-Abrantes, Juliano, Petrik, Colleen M., du Pontavice, Hubert, Richardson, Anthony J., Steenbeek, Jeroen, Tai, Travis C., Volkholz, Jan, Woodworth-Jefcoats, Phoebe A., and Tittensor, Derek P.

Published
2021
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7. Next-generation ensemble projections reveal higher climate risks for marine ecosystems

Author

Tittensor, Derek P., Novaglio, Camilla, Harrison, Cheryl S., Heneghan, Ryan F., Barrier, Nicolas, Bianchi, Daniele, Bopp, Laurent, Bryndum-Buchholz, Andrea, Britten, Gregory L., Büchner, Matthias, Cheung, William W. L., Christensen, Villy, Coll, Marta, Dunne, John P., Eddy, Tyler D., Everett, Jason D., Fernandes-Salvador, Jose A., Fulton, Elizabeth A., Galbraith, Eric D., Gascuel, Didier, Guiet, Jerome, John, Jasmin G., Link, Jason S., Lotze, Heike K., Maury, Olivier, Ortega-Cisneros, Kelly, Palacios-Abrantes, Juliano, Petrik, Colleen M., du Pontavice, Hubert, Rault, Jonathan, Richardson, Anthony J., Shannon, Lynne, Shin, Yunne-Jai, Steenbeek, Jeroen, Stock, Charles A., and Blanchard, Julia L.

Published
2021
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9. Energy Flow Through Marine Ecosystems: Confronting Transfer Efficiency

Author

Eddy, Tyler D., Bernhardt, Joey R., Blanchard, Julia L., Cheung, William W.L., Colléter, Mathieu, du Pontavice, Hubert, Fulton, Elizabeth A., Gascuel, Didier, Kearney, Kelly A., Petrik, Colleen M., Roy, Tilla, Rykaczewski, Ryan R., Selden, Rebecca, Stock, Charles A., Wabnitz, Colette C.C., and Watson, Reg A.

Published
2021
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10. The Past and Future of the Fisheries and Marine Ecosystem Model Intercomparison Project.

Author

Novaglio, Camilla, Bryndum‐Buchholz, Andrea, Tittensor, Derek P., Eddy, Tyler D., Lotze, Heike K., Harrison, Cheryl S., Heneghan, Ryan F., Maury, Olivier, Ortega‐Cisneros, Kelly, Petrik, Colleen M., Roberts, Kelsey E., and Blanchard, Julia L.

Subjects
CLIMATE change adaptation, MARINE biology, FISHERIES, MARINE ecology, FISHERY management, MARINE resources conservation
Abstract

Climate change is increasingly affecting the world's ocean ecosystems, necessitating urgent guidance on adaptation strategies to limit or prevent catastrophic impacts. The Fisheries and Marine Ecosystem Model Intercomparison Project (FishMIP) is a network and framework that provides standardised ensemble projections of the impacts of climate change and fisheries on ocean life and the benefits that it provides to people. Since its official launch in 2013 as a small, self‐organized project within the larger Inter‐Sectoral Impact Model Intercomparison Project, the FishMIP community has grown substantially and contributed to key international policy processes, such as the Intergovernmental Panel on Climate Change Assessment Report, and the Intergovernmental Science‐Policy Platform on Biodiversity and Ecosystem Services Global Biodiversity Assessment. While not without challenges, particularly around comparing heterogeneous ecosystem models, integrating fisheries scenarios, and standardising regional‐scale ecosystem models, FishMIP outputs are now being used across a variety of applications (e.g., climate change targets, fisheries management, marine conservation, Sustainable Development Goals). Over the next decade, FishMIP will focus on improving ecosystem model ensembles to provide more robust and policy‐relevant projections for different regions of the world under multiple climate and societal change scenarios, and continue to be open to a broad spectrum of marine ecosystem models and modelers. FishMIP also intends to enhance leadership diversity and capacity‐building to improve representation of early‐ and mid‐career researchers from under‐represented countries and ocean regions. As we look ahead, FishMIP aims to continue enhancing our understanding of how marine life and its contributions to people may change over the coming century at both global and regional scales. Plain Language Summary: The world's oceans are experiencing significant changes due to climate impacts, which are affecting marine ecosystems and fisheries. To address these challenges, the Fisheries and Marine Ecosystem Model Intercomparison Project (FishMIP) was launched in 2013. FishMIP brings together scientists to develop standardised projections of how climate change and fishing activities will impact ocean life and the benefits people get from fisheries. Despite some difficulties in comparing different ecosystem models and integrating fisheries scenarios, FishMIP's outputs are now informing various policy areas such as setting climate targets, managing fisheries, food security, and conserving marine environments. Over the next 10 years, FishMIP plans to improve its model ensembles to provide more reliable projections for different regions under various climate and societal change scenarios. Additionally, FishMIP aims to increase diversity in leadership and capacity‐building to involve more researchers from under‐represented countries and regions. Looking forward, FishMIP will continue to foster a global community of ecosystem and climate modelers, to enhance our understanding of how marine ecosystems and their benefits to people might change in the future, both globally and locally. Key Points: There is an urgent need for policy to develop strategies to adapt to the impacts of climate change on ecosystems and their servicesThe Fisheries and Marine Ecosystem Model Intercomparison Project has contributed understanding of climate impacts on marine ecosystemsThe next 10 years will see the improved FishMIP ensemble model pushing the boundaries of the field and increasing policy‐relevant outputs [ABSTRACT FROM AUTHOR]

Published
2024
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11. Key Uncertainties and Modeling Needs for Managing Living Marine Resources in the Future Arctic Ocean.

Author

Mason, Julia G., Bryndum‐Buchholz, Andrea, Palacios‐Abrantes, Juliano, Badhe, Renuka, Morgante, Isabella, Bianchi, Daniele, Blanchard, Julia L., Everett, Jason D., Harrison, Cheryl S., Heneghan, Ryan F., Novaglio, Camilla, and Petrik, Colleen M.

Subjects
MARINE resources, MARINE biology, GEOGRAPHICAL distribution of fishes, FISHERY closures, STRUCTURAL models, SEA ice, FISHERIES
Abstract

Emerging fishing activity due to melting ice and poleward species distribution shifts in the rapidly‐warming Arctic Ocean challenges transboundary management and requires proactive governance. A 2021 moratorium on commercial fishing in the Arctic high seas provides a 16‐year runway for improved scientific understanding. Given substantial knowledge gaps, characterizing areas of highest uncertainty is a key first step. Marine ecosystem model ensembles that project future fish distributions could inform management of future Arctic fisheries, but Arctic‐specific variation has not yet been examined for global ensembles. We use the Fisheries and Marine Ecosystem Intercomparison Project ensemble driven by two Earth System Models (ESMs) under two Shared Socioeconomic Pathways (SSP1‐2.6 and SSP5‐8.5) to illustrate the current state of and uncertainty among biomass projections for the Arctic Ocean over the duration of the moratorium. The models generally project biomass increases in more northern Arctic ecosystems and decreases in southern ecosystems, but wide intra‐model variation exceeds projection means in most cases. The two ESMs show opposite trends for the main environmental drivers. Therefore, these projections are currently insufficient to inform policy actions. Investment in sustained monitoring and improving modeling capacity, especially for sea ice dynamics, is urgently needed. Concurrently, it will be necessary to develop frameworks for making precautionary decisions under continued uncertainty. We conclude that researchers should be transparent about uncertainty, presenting these model projections not as a source of scientific "answers," but as bounding for plausible, policy‐relevant questions to assess trade‐offs and mitigate risks. Plain Language Summary: As the Arctic Ocean gets warmer, melting ice is opening up new opportunities for fishing. However, we don't know where fish will go and how they can be managed sustainably. An important first step is to figure out which unknowns we can solve quickly with more research, and what is so uncertain that we will have to make decisions without ideal information. In this paper, we looked at uncertainty in a set of global models that predict how fish populations might shift in the next 10–25 years. Overall, these models show that fish populations might increase in the northern parts of the Arctic while decreasing in the south. But the models make very different predictions, and some disagree on whether fish populations will increase or decrease in certain areas. A major source of uncertainty is how sea ice will change, and how ocean life will respond. Therefore, this is a priority area to invest in long‐term research and better models. Overall, these models are too uncertain to rely on for specific management decisions about Arctic fishing. Instead, scientists and decision makers can use them to shape more informed discussions about potential trade‐offs and risks of future fishing in the Arctic. Key Points: Variation and disagreement in marine ecosystem model projections are too high to be informative for near‐term Arctic fisheries managementInsufficient inclusion and knowledge of sea ice cover and sea ice productivity dynamics are major drivers of uncertaintyResearchers should be transparent about uncertainty and risk; present model projections as the basis for hypotheses and scenario planning [ABSTRACT FROM AUTHOR]

Published
2024
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14. Scenario setup and forcing data for impact model evaluation and impact attribution within the third round of the Inter-Sectoral Model Intercomparison Project (ISIMIP3a).

Author

Frieler, Katja, Volkholz, Jan, Lange, Stefan, Schewe, Jacob, Mengel, Matthias, del Rocío Rivas López, María, Otto, Christian, Reyer, Christopher P. O., Karger, Dirk Nikolaus, Malle, Johanna T., Treu, Simon, Menz, Christoph, Blanchard, Julia L., Harrison, Cheryl S., Petrik, Colleen M., Eddy, Tyler D., Ortega-Cisneros, Kelly, Novaglio, Camilla, Rousseau, Yannick, and Watson, Reg A.

Subjects
TROPICAL cyclones, TERRITORIAL waters, WATER levels, DATA modeling, WATER management, SEA level, CARBON dioxide
Abstract

This paper describes the rationale and the protocol of the first component of the third simulation round of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP3a, http://www.isimip.org , last access: 2 November 2023) and the associated set of climate-related and direct human forcing data (CRF and DHF, respectively). The observation-based climate-related forcings for the first time include high-resolution observational climate forcings derived by orographic downscaling, monthly to hourly coastal water levels, and wind fields associated with historical tropical cyclones. The DHFs include land use patterns, population densities, information about water and agricultural management, and fishing intensities. The ISIMIP3a impact model simulations driven by these observation-based climate-related and direct human forcings are designed to test to what degree the impact models can explain observed changes in natural and human systems. In a second set of ISIMIP3a experiments the participating impact models are forced by the same DHFs but a counterfactual set of atmospheric forcings and coastal water levels where observed trends have been removed. These experiments are designed to allow for the attribution of observed changes in natural, human, and managed systems to climate change, rising CH 4 and CO 2 concentrations, and sea level rise according to the definition of the Working Group II contribution to the IPCC AR6. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Demersal fish biomass declines with temperature across productive shelf seas.

Author

van Denderen, Daniel, Maureaud, Aurore A., Andersen, Ken H., Gaichas, Sarah, Lindegren, Martin, Petrik, Colleen M., Stock, Charles A., and Collie, Jeremy

Subjects
FISH declines, FISH communities, CONTINENTAL shelf, DREDGING (Fisheries), FISHING villages, FISHERIES
Abstract

Aim: Theory predicts fish community biomass to decline with increasing temperature due to higher metabolic losses resulting in less efficient energy transfer in warm‐water food webs. However, whether these metabolic predictions explain observed macroecological patterns in fish community biomass is virtually unknown. Here, we test these predictions by examining the variation in demersal fish biomass across productive shelf regions. Location: Twenty one continental shelf regions in the North Atlantic and Northeast Pacific. Time Period: 1980–2015. Major Taxa Studied: Marine teleost fish and elasmobranchs. Methods: We compiled high‐resolution bottom trawl survey data of fish biomass containing 166,000 unique tows and corrected biomass for differences in sampling area and trawl gear catchability. We examined whether relationships between net primary production and demersal fish community biomass are mediated by temperature, food‐web structure and the level of fishing exploitation, as well as the choice of spatial scale of the analysis. Subsequently, we examined if temperature explains regional changes in fish biomass over time under recent warming. Results: We find that biomass per km2 varies 40‐fold across regions and is highest in cold waters and areas with low fishing exploitation. We find no evidence that temperature change has impacted biomass within marine regions over the time period considered. The biomass variation is best explained by an elementary trophodynamic model that accounts for temperature‐dependent trophic efficiency. Main Conclusions: Our study supports the hypothesis that temperature is a main driver of large‐scale cross‐regional variation in fish community biomass. The cross‐regional pattern suggests that long‐term impacts of warming will be negative on biomass. These results provide an empirical basis for predicting future changes in fish community biomass and its associated services for human wellbeing that is food provisioning, under global climate change. [ABSTRACT FROM AUTHOR]

Published
2023
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17. Trophic amplification: A model intercomparison of climate driven changes in marine food webs.

Author

Guibourd de Luzinais, Vianney, du Pontavice, Hubert, Reygondeau, Gabriel, Barrier, Nicolas, Blanchard, Julia L., Bornarel, Virginie, Büchner, Matthias, Cheung, William W. L., Eddy, Tyler D., Everett, Jason D., Guiet, Jerome, Harrison, Cheryl S., Maury, Olivier, Novaglio, Camilla, Petrik, Colleen M., Steenbeek, Jeroen, Tittensor, Derek P., and Gascuel, Didier

Subjects
FOOD chains, CLIMATE change, GREENHOUSE gases, TOP predators, FISHERIES, MARINE biomass
Abstract

Marine animal biomass is expected to decrease in the 21st century due to climate driven changes in ocean environmental conditions. Previous studies suggest that the magnitude of the decline in primary production on apex predators could be amplified through the trophodynamics of marine food webs, leading to larger decreases in the biomass of predators relative to the decrease in primary production, a mechanism called trophic amplification. We compared relative changes in producer and consumer biomass or production in the global ocean to assess the extent of trophic amplification. We used simulations from nine marine ecosystem models (MEMs) from the Fisheries and Marine Ecosystem Models Intercomparison Project forced by two Earth System Models under the high greenhouse gas emissions Shared Socioeconomic Pathways (SSP5-8.5) and a scenario of no fishing. Globally, total consumer biomass is projected to decrease by 16.7 ± 9.5% more than net primary production (NPP) by 2090–2099 relative to 1995–2014, with substantial variations among MEMs and regions. Total consumer biomass is projected to decrease almost everywhere in the ocean (80% of the world's oceans) in the model ensemble. In 40% of the world's oceans, consumer biomass was projected to decrease more than NPP. Additionally, in another 36% of the world's oceans consumer biomass is expected to decrease even as projected NPP increases. By analysing the biomass response within food webs in available MEMs, we found that model parameters and structures contributed to more complex responses than a consistent amplification of climate impacts of higher trophic levels. Our study provides additional insights into the ecological mechanisms that will impact marine ecosystems, thereby informing model and scenario development. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Scenario set-up and forcing data for impact model evaluation and impact attribution within the third round of the Inter-Sectoral Model Intercomparison Project (ISIMIP3a).

Author

Frieler, Katja, Volkholz, Jan, Lange, Stefan, Schewe, Jacob, Mengel, Matthias, del Rocío Rivas López, María, Otto, Christian, Reyer, Christopher P. O., Karger, Dirk Nikolaus, Malle, Johanna T., Treu, Simon, Menz, Christoph, Blanchard, Julia L., Harrison, Cheryl S., Petrik, Colleen M., Eddy, Tyler D., Ortega-Cisneros, Kelly, Novaglio, Camilla, Rousseau, Yannick, and Watson, Reg A.

Subjects
TROPICAL cyclones, TERRITORIAL waters, DATA modeling, WATER levels, WATER management, SEA level, DOWNSCALING (Climatology)
Abstract

This paper describes the rationale and the protocol of the first component of the third simulation round of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP3a, www.isimip.org) and the associated set of climate-related and direct human forcing data (CRF and DHF, respectively). The observation-based climate-related forcings for the first time include high-resolution observational climate forcings derived by orographic downscaling, monthly to hourly coastal water levels, and wind fields associated with historical tropical cyclones. The DHFs include land use patterns, population densities, information about water and agricultural management, and fishing intensities. The ISIMIP3a impact model simulations driven by these observation-based climate-related and direct human forcings are designed to test to what degree the impact models can explain observed changes in natural and human systems. In a second set of ISIMIP3a experiments the participating impact models are forced by the same DHFs but a counterfactual set of atmospheric forcings and coastal water levels where observed trends have been removed. These experiments are designed to allow for the attribution of observed changes in natural, human and managed systems to climate change, rising CH4 and CO2 concentrations, and sea level rise according to the definition of the Working Group II contribution to the IPCC AR6. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Model estimates of metazoans' contributions to the biological carbon pump.

Author

Pinti, Jérôme, DeVries, Tim, Norin, Tommy, Serra-Pompei, Camila, Proud, Roland, Siegel, David A., Kiørboe, Thomas, Petrik, Colleen M., Andersen, Ken H., Brierley, Andrew S., and Visser, André W.

Subjects
FISH migration, CARBON sequestration, ANIMAL droppings, CARBON, FUNCTIONAL groups, EDIACARAN fossils, ATMOSPHERIC oxygen
Abstract

The daily vertical migrations of fish and other metazoans actively transport organic carbon from the ocean surface to depth, contributing to the biological carbon pump. We use an oxygen-constrained, game-theoretic food-web model to simulate diel vertical migrations and estimate near-global (global ocean minus coastal areas and high latitudes) carbon fluxes and sequestration by fish and zooplankton due to respiration, fecal pellets, and deadfalls. Our model provides estimates of the carbon export and sequestration potential for a range of pelagic functional groups, despite uncertain biomass estimates of some functional groups. While the export production of metazoans and fish is modest (∼20 % of global total), we estimate that their contribution to carbon sequestered by the biological pump (∼800 PgC) is conservatively more than 50 % of the estimated global total (∼1300 PgC) and that they have a significantly longer sequestration timescale (∼250 years) than previously reported for other components of the biological pump. Fish and multicellular zooplankton contribute about equally to this sequestered carbon pool. This essential ecosystem service could be at risk from both unregulated fishing on the high seas and ocean deoxygenation due to climate change. [ABSTRACT FROM AUTHOR]

Published
2023
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23. Model estimates of metazoans' contributions to the biological carbon pump.

Author

Pinti, Jérôme, DeVries, Tim, Norin, Tommy, Serra-Pompei, Camila, Proud, Roland, Siegel, David A., Kiorboe, Thomas, Petrik, Colleen M., Andersen, Ken H., Brierley, Andrew S., and Visser, André W.

Subjects
FISH migration, CARBON sequestration, ANIMAL droppings, COLLOIDAL carbon, CARBON, FUNCTIONAL groups
Abstract

The daily vertical migrations of fish and other metazoans actively transport organic carbon from the ocean surface to depth, contributing to the biological carbon pump. We use an oxygen-constrained, game-theoretic food-web model to simulate diel vertical migrations and estimate global carbon fluxes and sequestration by fish and zooplankton due to respiration, fecal pellets, and deadfalls. Our model provides estimates of the carbon export and sequestration potential for a range of pelagic functional groups, despite uncertain biomass estimates of some functional groups. While the export production of metazoans 5 and fish is modest (~20% of global total), we estimate that their contribution to carbon sequestered by the biological pump (~800 PgC) is conservatively more than 50% of the estimated global total (~1300 PgC) and have a significantly longer sequestration time scale (~250 years) than previously reported for other components of the biological pump. Fish and multicellular zooplankton contribute about equally to this sequestered carbon pool. This essential ecosystem service could be at risk from both unregulated fishing on the high seas and ocean deoxygenation due to climate change. [ABSTRACT FROM AUTHOR]

Published
2022
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25. Emergent global biogeography of marine fish food webs.

Author

van Denderen, P. Daniël, Petrik, Colleen M., Stock, Charles A., Andersen, Ken H., and Bates, Amanda

Subjects
*FISH food, *MARINE fishes, *CONTINENTAL slopes, *BIOGEOGRAPHY, *PELAGIC fishes, *NUTRIENT cycles, *FISH communities, *FISHERIES
Abstract

Aim: Understanding how fish food webs emerge from planktonic and benthic energy pathways that sustain them is an important challenge for predicting fisheries production under climate change and quantifying the role of fish in carbon and nutrient cycling. We examine if a trait‐based fish community model using the fish traits of maximum body weight and vertical habitat strategy can meet this challenge by globally representing fish food web diversity. Location: Global oceans. Time period: Predictions are representative of the early 1990s. Major taxa studied: Marine teleost fish. Methods: We present a size‐ and trait‐based fish community model that explicitly resolves the dependence of fish on pelagic and benthic energy pathways to globally predict fish food web biogeography. The emergent food web structures are compared with regionally calibrated models in three different ecosystem types and used to estimate two fish ecosystem functions: potential fisheries production and benthic–pelagic coupling. Results: Variations in pelagic–benthic energy pathways and seafloor depth drive the emergent biogeography of fish food webs from shelf systems to the open ocean, and across the global ocean. Most shelf regions have high benthic production, which favours demersal fish that feed on pelagic and benthic pathways. Continental slopes also show a coupling of benthic and pelagic pathways, sustained through vertically migrating and interacting mesopelagic and deep‐sea demersal fish. Open ocean fish communities are primarily structured around the pelagic pathway. Global model results compare favourably with data‐driven regional food web models, suggesting that maximum weight and vertical behaviour can capture large‐scale variations in food web structure. Main conclusions: Mechanistically linking ocean productivity with upper trophic levels using a size‐ and trait‐based fish community model results in spatial variations in food web structure. Energy pathways vary with ocean productivity and seabed depth, thereby shaping the dominant traits and fish communities across ocean biomes. [ABSTRACT FROM AUTHOR]

Published
2021
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26. An updated life-history scheme for marine fishes predicts recruitment variability and sensitivity to exploitation.

Author

Petrik, Colleen M., González Taboada, Fernando, Stock, Charles A., and Sarmiento, Jorge L.

Subjects
*FISH populations, *OSTEICHTHYES, *CHONDRICHTHYES, *LIFE spans, *LONGEVITY, *MARINE fishes
Abstract

Aim: Patterns of population renewal in marine fishes are often irregular and lead to volatile fluctuations in abundance that challenge management and conservation efforts. Here, we examine the relationship between life-history strategies and recruitment variability in exploited marine fish species using a macroecological approach. Location: Global ocean. Time period: 1950-2018. Major taxa studied: Bony and cartilaginous fish. Methods: Based on trait data for 244 marine fish species, we extend the established equilibrium--periodic--opportunistic (E-P-O) life-history classification scheme objectively to include two additional emergent life-history strategies: "bet-hedgers" (B) and salmonic (S) strategists. The B strategists include rockfishes and other species inhabiting patchy benthic habitats with life histories that blend characteristics of E and P species; they combine very long life spans with elevated investments in both parental care and fecundity. The S strategists mainly comprise salmonids that share life-history characteristics with E and O species: elevated investments in parental care reminiscent of E strategists, but with reduced fecundity and short life spans characteristic of O species. We analysed how the E-B-P-O-S life-history classification mapped onto patterns of recruitment variability observed in population time series data (n = 156 species). Results: Generalized linear models suggested that life-history strategy explained a modest, yet significant amount of recruitment variability across species. Greater predictive power arose after controlling for increased recruitment variance associated with variable fishing pressure, with O strategists showing the strongest sensitivity. The B strategists were susceptible to exploitation in a similar manner to P stocks, but their longer times to maturity made them particularly vulnerable to overfishing. Main conclusions: A broader recognition of the distinct ecology of salmonic and bethedger groups is important when studying life-history strategies in marine fish. More generally, our results stress the importance of considering life-history strategies for understanding patterns of recruitment variability across fish stocks. [ABSTRACT FROM AUTHOR]

Published
2021
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27. Modelling the sources of mortality for larval haddock on Georges Bank and their effects on behavior

Author

Petrik, Colleen M., Davis, Cabell S., Ji, Rubao, Lough, R. G., and Kristiansen, Trond

Subjects
haddock, fish behaviour, fiskeatferd, mortality, dødelighet, VDP::Agriculture and fishery disciplines: 900::Fisheries science: 920::Resource biology: 921, hyse
Abstract

Fish larvae have the ability to change their vertical position in the water column and thusly cannot be treated as passive particles in coupled biological-physical individualbased models (IBMs). The vertical variability of light, turbulence, temperature, prey, predators, and horizontal currents in the ocean affects the survival of larval fish through effects on feeding, growth, advection, and predation mortality. A dynamic model of the vertical position of larval fish in response to individual state and environmental conditions is needed for use in three-dimensional IBMs. A 1-dimensional model was constructed of an idealized water column representative of spring conditions on the southern flank of Georges Bank. The water column was used to test six behavioral rules of individuals parameterized as larval haddock (Melanogrammus aeglefinus) under different conditions of prey and turbulence stratification. Our objectives were to determine how behaviors based on different state and environmental variables affect depth distribution and mortality, and which behaviors produce a vertical distribution most similar to observations. Individuals applying behaviors associated with feeding had distributions comparable to observations and the highest survival. The use of behaviors derived from a trade-off between gut fullness and visual predation led to distributions unlike observations and high starvation mortality of the largest larval size class. Results suggest that larvae should make their vertical behavior decisions based on the risk of starvation rather than predation. A realistic model of larval haddock vertical position could be developed using only behaviors related to its prey distribution and foraging success.

Published
2009

28. Modelled connectivity between Walleye Pollock (Gadus chalcogrammus) spawning and age-0 nursery areas in warm and cold years with implications for juvenile survival.

Author

Petrik, Colleen M., Duffy-Anderson, Janet T., Castruccio, Frederic, Curchitser, Enrique N., Danielson, Seth L., Hedstrom, Katherine, and Mueter, Franz

Subjects
*WALLEYE pollock, *SPAWNING, *WALLEYE (Fish), *GEOGRAPHICAL distribution of fishes, *SIMULATION methods & models
Abstract

Adult and early life stage distributions of the commercially important demersal fish Walleye Pollock (Gadus chalcogrammus) have varied in relation to the warm and cold environmental conditions on the eastern Bering Sea (EBS) shelf. Previous modelling studies indicate that transport alone does not account for the disparate juvenile distributions in warm and cold years, but that spawning locations are important. Our objective was to determine the potential connectivity of EBS pollock spawning areas with juvenile nursery areas between warm and cold years from an 18-year hindcast (1995–2012). We calculated the connectivity between larval sources and juvenile positions that were produced by a coupled biological-physical individual-based model that simulated transport, growth, and vertical behavior of pollock from the egg until the juvenile stage. Three connectivity patterns were seen in most simulations: along-isobaths to the northwest, self-retention, and transport around the Pribilof Islands. The major differences in connectivity between warm and cold years, more northwards in warm years and more off-shelf in cold years, mimicked wind-driven flow characteristics of those years that were related to winter mean zonal position of the Aleutian Low. Connectivity relationships were more sensitive to spatial alterations in the spawning areas in cold years, while they were more responsive to spawn timing shifts in warm years. The strongest connectivity to advantageous juvenile habitats originated in the well-known spawning areas, but also in a less well-studied region on the Outer Shelf. This northern Outer Shelf region emerged as a very large sink of pollock reaching the juvenile transition from all spawning sources, suggesting more thorough sampling across multiple trophic levels of this potentially important juvenile pollock nursery is needed. [ABSTRACT FROM AUTHOR]

Published
2016
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29. Interannual differences in larval haddock survival: hypothesis testing with a 3D biophysical model of Georges Bank.

Author

Petrik, Colleen M., Ji, Rubao, and Davis, Cabell S.

Subjects
*HADDOCK fisheries, *BIOPHYSICAL labeling, *STATISTICAL hypothesis testing, *FISH populations, *FISH larvae, *FISH metabolism
Abstract

The ultimate goal of early life studies of fish over the past century has been to better understand recruitment variability. As evident in the Georges Bank haddock ( Melanogrammus aeglefinus) population, there is a strong relationship between recruitment success and processes occurring during the planktonic larval stage. This research sought new insights into the mechanisms controlling the recruitment process in fish populations using biological-physical modeling methods together with laboratory and field data sets. We created the first three-dimensional model of larval haddock on Georges Bank by coupling models of hydrodynamics, lower trophic levels, a single copepod species, and larval haddock. Interactions between feeding, metabolism, growth, vertical behavior, advection, predation, and the physical environment of larval haddock were quantitatively investigated using the coupled models. Particularly, the model was used to compare survival over the larval period and the sources of mortality in 1995 and 1998, 2 years of disparate haddock recruitment. The results of model simulations suggest that the increased egg hatching rates and higher food availability, which reduced starvation and predation, in 1998 contributed to its larger year-class. Additionally, the inclusion of temperature-dependent predation rates produced model results that better agreed with observations of the mean hatch date of survivors. The results from this biophysical model imply that food limitation and its related losses to starvation and predation, especially from hatch to 7 mm, may be responsible for interannual variability in recruitment and larval survival outside of the years studied. [ABSTRACT FROM AUTHOR]

Published
2014
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