The Baltic Sea Action Plan and the EU Water Framework Directive both require substantial additional reductions of nutrient loads (N and P) to the marine environment. Focusing on nitrogen, we present a widely applicable concept for spatially differentiated regulation, exploiting the large spatial variations in the natural removal of nitrate in groundwater and surface water. By targeting mitigation measures towards areas where nature’s own capacity for removal is low, spatially differentiated regulation can be more cost-effective than the traditional uniform regulation. We present a methodology for upscaling local modelling results on targeted measures at field scale to Baltic Sea drainage basin scale. The paper assesses the potential gain and discusses key challenges related to implementation of spatially differentiated regulation, including the need for more scientific knowledge, handling of uncertainties, practical constraints related to agricultural practice and introduction of co-governance regimes.
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This work was carried out as part of the BONUS SOILS2SEA project (www.Soils2Sea.eu), which received funding from BONUS (Art 185), funded jointly by the EU and Innovation Fund Denmark, The Swedish Environmental Protection Agency, The Polish National Centre for Research and Development, The German Ministry for Education and Research and The Russian Foundation for Basic Research (RFBR).
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Refsgaard, J.C., Hansen, A.L., Højberg, A.L. et al. Spatially differentiated regulation: Can it save the Baltic Sea from excessive N-loads?. Ambio 48, 1278–1289 (2019). https://doi.org/10.1007/s13280-019-01195-w
- Baltic Sea drainage basin
- EU Water Framework Directive
- N-loads from agriculture
- Spatially differentiated regulation