Spatially differentiated strategies for reducing nitrate loads from agriculture in two Danish catchments

Abstract Nutrient loss from agriculture is the largest source of diffuse water pollution in Denmark. To reduce nutrient loads a number of solutions have been implemented, but this has been insufficient to achieve the environmental objectives without unacceptable repercussions for agricultural production. This has substantiated the need to develop a new approach to achieve nitrogen (N) load reductionto the aquatic environments with lower costs to farmers. The new approach imply targeting N leaching mitigation to those parts of the landscape which contribute most to the N-loadings. This would involve either reducing the source loading or enhancing the natural reduction(denitrification) of N after it is leached from the root zone of agricultural crops. In this study, a new method of spatially differentiated analysis for two Danish catchments (Odense and Norsminde) was conducted that reach across the individual farms to achieve selected N-load reductiontargets. It includes application of cover cropswithin current crop rotations, set-a-side application on high N-load areas, and changes in agricultural management based on maps of N- reductionavailable for two different spatial scales, considering soil typeand farm boundaries as spatial constraints. In summary, the results revealed that considering spatial constraints for changes in agricultural management will affect the effectiveness of N-load reduction, and the highest N-load reductionwas achieved where less constraints were considered. The results also showed that the range of variation in land use, soil types, and N- reductionpotential influence the reductionof N-loadings that can originate from critical source areas. The greater the spatial variation the greater the potential for N load reductionthrough targeting of measures. Therefore, the effectiveness of spatially differentiated measures in term of set-a-side area in Odense catchment were relatively greater compared to Norsminde catchment. The results also showed that using a fine spatial N- reductionmap provides greater potential for N load reductionscompared to using sub-catchment scale N- reductionmaps.