The Arctic Ocean is warming up and an increasing freshwater inflow is triggering major changes in ocean
layers. This model study aims at creating a baseline, and analyzing the effect of freshwater content
changes, subsequent freshwater sealing as well as related parameters in the Arctic Ocean on migration and
life history of zooplankton such as copepods and euphausiids. Copepods and euphausiids make for a major
part of the zooplankton biomass in the Arctic Ocean, and are an important part of the food chain. Analyses
are carried out using an ecosystem-based, spatial modeling approach with machine learning algorithms
(Salford Systems TreeNet®, Random Forests® and R implementations). The underlying data consists of over
100 predictors including a globally unique data set of physical oceanography. Raw data that was used in this
project is available as metadata from the Core Science Metadata Clearinghouse (former National Biological
Information Infrastructure) and available at http://mercury.ornl.gov/clearinghouse/ and on servers from
the University of Alaska Fairbanks. The Canadian Earth System Model 2 (CanESM2) was utilized to model
the effect of changing climate on zooplankton for the next 100 years and for a low emission (RCP26) and a
high emission scenario (RCP85). The results consist of spatially explicit (where every point in the layer is geo
referenced) and predicted layers for Geographic Information Systems (GIS) that show predicted plankton
presence/random absence as well as the relative index of depth and life stage distribution where the
zooplankton is most likely to occur. The models show a clear trend towards an increasing relative index of
depth where zooplankton is most likely to be found for the year 2100. Moreover, a trend towards a
diminishing ecological niche for adult life stages of zooplankton was observed. These changes add stress to
the life of zooplankton, especially regarding the diel vertical migration of mostly adult life stages. If
zooplankton has to migrate a longer way, this will most likely increase energy expenditure and predation
risk which ultimately decreases fitness. When accounting for other man-made impacts on the ocean such
as ocean acidification and increasing shipping in the Arctic and taking the big picture into account, the
outlook and conditions for zooplankton in 2100 are negative.Abstract -- Acknowledgements -- List of Abbreviations -- Units -- Content -- List of Figures -- List of Tables -- 1: Introduction -- 2: Methods -- 3: Results -- Discussion -- References -- Appendi

Schmid, Moritz

English

Dt. Titel: Vorhersagemodelle für den Einfluss von Süßwasser
Einstrom auf Salzwasser Schichten, Wanderbewegung
und Lebenszyklen des Zooplankton im Arktischen
Ozean: Szenarien und Trends in der ZukunftThe Arctic Ocean is warming up and an increasing freshwater inflow is triggering major changes in ocean
layers. This model study aims at creating a baseline, and analyzing the effect of freshwater content
changes, subsequent freshwater sealing as well as related parameters in the Arctic Ocean on migration and
life history of zooplankton such as copepods and euphausiids. Copepods and euphausiids make for a major
part of the zooplankton biomass in the Arctic Ocean, and are an important part of the food chain. Analyses
are carried out using an ecosystem-based, spatial modeling approach with machine learning algorithms
(Salford Systems TreeNet®, Random Forests® and R implementations). The underlying data consists of over
100 predictors including a globally unique data set of physical oceanography. Raw data that was used in this
project is available as metadata from the Core Science Metadata Clearinghouse (former National Biological
Information Infrastructure) and available at http://mercury.ornl.gov/clearinghouse/ and on servers from
the University of Alaska Fairbanks. The Canadian Earth System Model 2 (CanESM2) was utilized to model
the effect of changing climate on zooplankton for the next 100 years and for a low emission (RCP26) and a
high emission scenario (RCP85). The results consist of spatially explicit (where every point in the layer is geo
referenced) and predicted layers for Geographic Information Systems (GIS) that show predicted plankton
presence/random absence as well as the relative index of depth and life stage distribution where the
zooplankton is most likely to occur. The models show a clear trend towards an increasing relative index of
depth where zooplankton is most likely to be found for the year 2100. Moreover, a trend towards a
diminishing ecological niche for adult life stages of zooplankton was observed. These changes add stress to
the life of zooplankton, especially regarding the diel vertical migration of mostly adult life stages. If
zooplankton has to migrate a longer way, this will most likely increase energy expenditure and predation
risk which ultimately decreases fitness. When accounting for other man-made impacts on the ocean such
as ocean acidification and increasing shipping in the Arctic and taking the big picture into account, the
outlook and conditions for zooplankton in 2100 are negative

Georg-August-University Göttingen

Model-predicting the effect of freshwater inflow on saltwater layers, migration and life history of zooplankton in the Arctic Ocean: Towards scenarios and future trends

ScholarWorks@UA

Model-predicting the Effect of Freshwater Inflow on Saltwater Layers, Migration and Life History of Zooplankton in the Arctic Ocean: Towards Scenarios and Future Trends

https://scholarworks.alaska.edu/bitstream/11122/5116/1/Schmid_Moritz_M.Sc_thesis_FINAL.pdf

Model-predicting the Effect of Freshwater Inflow on Saltwater Layers, Migration and Life History of Zooplankton in the Arctic Ocean: Towards Scenarios and Future Trends

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Georg-August-University Göttingen

ScholarWorks@UA