Affiliation:
1. Bioeconomy and Environment Unit, Sustainability Science and Indicators Natural Resources Institute Finland (Luke) Turku Finland
2. Bioeconomy and Environment Unit, Bioeconomy Policies and Markets Natural Resources Institute Finland (Luke) Helsinki Finland
3. Department of Forest and Soil Sciences Institute of Soil Research (IBF), University of Natural Resources and Life Sciences, Vienna (BOKU) Vienna Austria
4. Department of Bioeconomy and System Analysis Institute of Soil Science and Plant Cultivation – State Research Institute (IUNG) Puławy Poland
5. Department of Biogeochemistry and Soil Quality Norwegian Institute of Bioeconomy Research (NIBIO) Ås Norway
6. Plant Sciences Unit Flanders Research Institute for Agriculture, Fisheries and Food (ILVO) Merelbeke Belgium
Abstract
AbstractSoil management strategies involving the application of organic matter (OM) inputs (crop residues, green and livestock manure, slurry, digestate, compost and biochar) can increase soil carbon storage but simultaneously lead to an increase in non‐CO2 greenhouse gas (GHG) emissions such as N2O. Although multiple meta‐analyses have been conducted on the topic of OM input impacts on GHG, none has focused specifically on European arable soils. This study plugs this gap and can assist policymakers in steering European agriculture in a more sustainable direction. The objective of this meta‐analysis was to quantify how OM inputs of different nature and quality, but also the application strategy, can mitigate soil N2O emissions in different pedoclimatic conditions in Europe. We quantitatively synthesised the results of over 50 field experiments conducted in 15 European countries. Diverse arable crops, mainly cereals, were cultivated in monoculture or in crop rotations on mineral soils. Cumulative N2O emissions were monitored during periods of 30–1070 days in treatments, which received OM inputs, alone or in combination with mineral N fertiliser; and in controls fertilised with mineral N. The overall effect of OM inputs had a slight tendency to reduce N2O emissions by 10% (n = 53). With the increasing carbon‐to‐nitrogen ratio of the OM inputs, this mitigation effect became more pronounced. In particular, compost and biochar significantly reduced N2O emissions by 25% (n = 6) and 33% (n = 8) respectively. However, their effect strongly depended on pedoclimatic characteristics. Regarding the other types of OM inputs studied, a slight N2O emission reduction can be achieved by their application alone, without mineral N fertiliser (by 16%, n = 17). In contrast, their co‐application with mineral N fertiliser elevated emissions to some extent compared to the control (by 14%, n = 22). We conclude that amongst the seven OM inputs studied, the application of compost and biochar are the most promising soil management practices, clearly demonstrating N2O emission reduction compared to mineral N fertiliser. In contrast, other OM inputs had a small tendency to mitigate N2O emissions only when applied without mineral N fertiliser.
Funder
Horizon 2020 Framework Programme
Cited by
1 articles.
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