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Increasing the cost-effectiveness of water quality improvements through pollution abatement target-setting at different spatial scales

Author

Listed:
  • Mikołaj Czajkowski

    (Faculty of Economic Sciences, University of Warsaw)

  • Hans E. Andersen

    (Department of Bioscience, Aarhus University)

  • Gite Blicher-Mathiasen

    (Department of Bioscience, Aarhus University
    Faculty of Economic Sciences, University of Warsaw)

  • Wiktor Budziński

    (Faculty of Economic Sciences, University of Warsaw)

  • Katarina Elofsson

    (Department of Bioscience, Aarhus University)

  • Jan Hagemejer

    (Faculty of Economic Sciences, University of Warsaw)

  • Berit Hasler

    (Department of Bioscience, Aarhus University)

  • Christoph Humborg

    (Department of Environmental Science, Stockholm University)

  • James C. R. Smart

    (Australian Rivers Institute, Griffith University)

  • Erik Smedberg

    (Department of Environmental Science, Stockholm University)

  • Per Stålnacke

    (Department of Water Resources, Norwegian Institute of Bioeconomy Research)

  • Hans Thodsen

    (Department of Bioscience, Aarhus University)

  • Adam Wąs

    (Warsaw University of Life Sciences, Faculty of Economic Sciences)

  • Maciej Wilamowski

    (Faculty of Economic Sciences, University of Warsaw)

  • Tomasz Żylicz

    (Faculty of Economic Sciences, University of Warsaw)

  • Nick Hanley

    (Animal Health and Comparative Medicine, University of Glasgow, Institute of Biodiversity)

Abstract

In this paper, we investigate the potential gains in cost-effectiveness from changing the spatial scale at which nutrient reduction targets are set for the Baltic Sea, focusing on nutrient loadings associated with agriculture. Costs of achieving loadings reductions are compared across five levels of spatial scale, namely the entire Baltic Sea; the marine basin level; the country level; the watershed level; and the grid square level. A novel highly disaggregated model, which represents decreases in agricultural profits, changes in root zone N concentrations and transport to the Baltic Sea is proposed, and is then used to estimate the gains in cost-effectiveness from changing the spatial scale of nutrient reduction targets. The model includes 14 Baltic Sea marine basins, 14 countries, 117 watersheds and 19,023 10-by-10 km grid squares. A range of policy options are identified which approach the cost-effective reductions in N loadings identified by the constrained optimization model. We argue that our results have important implications for both domestic and international policy design for achieving water quality improvements where non-point pollution is a key stressor of water quality.

Suggested Citation

  • Mikołaj Czajkowski & Hans E. Andersen & Gite Blicher-Mathiasen & Wiktor Budziński & Katarina Elofsson & Jan Hagemejer & Berit Hasler & Christoph Humborg & James C. R. Smart & Erik Smedberg & Per Ståln, 2020. "Increasing the cost-effectiveness of water quality improvements through pollution abatement target-setting at different spatial scales," Working Papers 2020-02, Faculty of Economic Sciences, University of Warsaw.
    • Handle: RePEc:war:wpaper:2020-02
    as

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    References listed on IDEAS

    as
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    More about this item

    Keywords

    cost-effectiveness; nutrient pollution; agricultural run-off; Baltic Sea; eutrophication;
    All these keywords.

    JEL classification:

    • Q52 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Environmental Economics - - - Pollution Control Adoption and Costs; Distributional Effects; Employment Effects
    • Q53 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Environmental Economics - - - Air Pollution; Water Pollution; Noise; Hazardous Waste; Solid Waste; Recycling
    • Q18 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Agriculture - - - Agricultural Policy; Food Policy; Animal Welfare Policy
    • Q25 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Renewable Resources and Conservation - - - Water
    • F53 - International Economics - - International Relations, National Security, and International Political Economy - - - International Agreements and Observance; International Organizations
    • R52 - Urban, Rural, Regional, Real Estate, and Transportation Economics - - Regional Government Analysis - - - Land Use and Other Regulations

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