Abstract
Climate change impact studies for the Northwest European Shelf (NWES) make use of various dynamical downscaling strategies in the experimental setup of regional ocean circulation models. Projected change signals from coupled and uncoupled downscalings with different domain sizes and forcing global and regional models show substantial uncertainty. In this paper, we investigate influences of the downscaling strategy on projected changes in the physical and biogeochemical conditions of the NWES. Our results indicate that uncertainties due to different downscaling strategies are similar to uncertainties due to the choice of the parent global model and the downscaling regional model. Downscaled change signals reveal to depend stronger on the downscaling strategy than on the model skills in simulating present-day conditions. Uncoupled downscalings of sea surface temperature (SST) changes are found to be tightly constrained by the atmospheric forcing. The incorporation of coupled air–sea interaction, by contrast, allows the regional model system to develop independently. Changes in salinity show a higher sensitivity to open lateral boundary conditions and river runoff than to coupled or uncoupled atmospheric forcings. Dependencies on the downscaling strategy for changes in SST, salinity, stratification and circulation collectively affect changes in nutrient import and biological primary production.
Highlights
Over the past years, the emerging impacts of climate change on the Northwest European Shelf (NWES) circulation system and marine ecosystem have caused serious concern (e.g. OSPAR 2000; BACC II Author Team 2015; Quante and Colijn 2016)
The projected signal is stronger in Cref than in MPI-ESM in the entire North Sea and Baltic Sea as well as in the northeastern North Atlantic
From the presented model experiments we conclude that for the NWES, the incorporation of coupled air–sea interaction in dynamical downscalings of global climate projections is essential for the regional model system to develop independent results
Summary
The emerging impacts of climate change on the Northwest European Shelf (NWES) circulation system and marine ecosystem have caused serious concern (e.g. OSPAR 2000; BACC II Author Team 2015; Quante and Colijn 2016). The NWES is a biologically rich and productive region, inhabited naturally by diverse species of all trophic levels. Its marine ecosystem is characterized by a complex network of interactions between biota and the physical and chemical environment. The NWES is one of the most frequently traversed sea areas in the world. Understanding the effects that climate change might have on the NWES dynamical system is key to account for both the economic interests and the integrity of the ecosystem functioning
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