Effect of crop residue incorporation on soil organic carbon and greenhouse gas emissions in European agricultural soils / Lehtinen T.; Schlatter N.; Baumgarten A.; Bechini L.; Krüger J.; Grignani C.; Zavattaro L.; Costamagna C.; Spiegel H.;. -In: SOIL USE AND MANAGEMENT. -ISSN 0266-0032. -STAMPA. -30(2014), pp. 524-538.
Original Citation:Effect of crop residue incorporation on soil organic carbon and greenhouse gas emissions in European agricultural soils
Published version:DOI:10.1111/sum.12151
Terms of use:Open Access (Article begins on next page) Anyone can freely access the full text of works made available as "Open Access". Works made available under a Creative Commons license can be used according to the terms and conditions of said license. Use of all other works requires consent of the right holder (author or publisher) if not exempted from copyright protection by the applicable law. intensive cropping systems. Incorporation of crop residues (CR) may be a sustainable 32 management practice to maintain the SOC levels and to increase soil fertility. This study 33 quantifies the effects of CR incorporation on SOC and greenhouse gas (GHG) emissions (CO2 and 34 N2O) in Europe using data from long-term experiments. Response ratios (RRs) for SOC and GHG 35 emissions were calculated between CR incorporation and removal. The influences of 36 environmental zones (ENZs), clay content and experiment duration on the RRs were 37 investigated. We also studied how RRs of SOC and crop yields were correlated. A total of 718 RRs 38 were derived from 39 publications. The SOC increased by 7 % following CR incorporation. In 39 contrast, in a subsample of cases, CO2 emissions were six times and N2O emissions 12 times 40 higher following CR incorporation. The ENZ had no significant influence on RRs. For SOC 41 concentration, soils with a clay content >35 % showed 8 % higher RRs compared to soils with 42 clay contents between 18 and 35 %. As the experiment progressed, RR for SOC concentration 43 and stock increased. For N2O emissions, RR was significantly higher in experiments with a 44 duration <5 years compared to 11-20 years. No significant correlations were found between RR 45 for SOC concentration and yields, but differences between sites and study durations were 46 detected. We suggest a win-win scenario to be crop residue incorporation for a long duration in 47 a continental climate, whereas the worst-case scenario involves crop residue incorporation over 48 the short term in the Mediterranean, especially with vegetative material. We conclude that CR 49 incorporation is important for maintaining SOC, but its influence on GHG emissions should be 50 taken into account as well. 51 52
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Remogna for their technical assistance. We also extend our appreciation to the anonymous reviewers who provided useful suggestions for improvement of this paper. This publication is the result of a FISR project funded by the Italian Ministry of Agriculture and Forestry.
1Mitigating the impact of fertilization on global warming: can leguminous green manure and compost help to reduce N 2 O and CO 2 emissions? ABSTRACT Alternative nitrogen fertilizers that stimulate low greenhouse gas emissions from soil are needed to reduce the impact of agriculture on global warming. Corn (Zea mais, L.) grown in a calcareous silt loam soil in northwestern Italy was fertilized with a municipal solid waste compost and vetch green manure (Vicia villosa, Roth.). Their potential to reduce N 2 O and CO 2 emissions was compared to that of urea (130 kg N ha -1 ). Gaseous fluxes were measured for two years in the spring (after soil incorporation of fertilizers) and in summer. In spring, the slow mineralization of compost reduced N 2 O emissions (0.11 % of supplied N) relative to urea (3.4 % of applied N), without an increase in CO 2 fluxes. Nitrous oxide (2.31 % of fixed N) and CO 2 emissions from rapid vetch decomposition did not differ from urea. When N 2 O and CO 2 fluxes were combined, compost reduced by 49% the CO 2 equivalent emitted following urea application. Vetch did not show such an effect. In summer, no fertilizer effect was found on N 2 O and CO 2 emissions. Compost proved to be potentially suitable to reduce CO 2 equivalent emitted after soil incorporation while vetch did not.For a thorough evaluation, net greenhouse gas emissions assessment should be extended to the entire N life cycle. Differences between calculated N 2 O emission factors and the default Tier 1 IPCC value (1%) confirmed the need for site-and fertilizer-specific estimations.Abbreviations: ΔCO 2 eq, increase of emitted CO 2 equivalent due to the applied fertilizer N respect to absence of fertilization; COM, fertilization with compost; CK, check plots not fertilized with N; EF, nitrous oxide emission factor of fertilizer N applied; GHG, greenhouse gas; LGM, fertilization with a leguminous green manure (hairy vetch); Ndfa, N derived from the atmosphere and fixed by a legume; PD, potential denitrification; PMN, N potentially mineralizable in anaerobiosis; SOC, soil organic carbon; SON, soil organic nitrogen; UR, fertilization with urea; WFPS, water-filled pore space.
Alternative management practices such as no‐tillage compared to conventional tillage are expected to recover or increase soil quality and productivity, even though all of these aspects are rarely studied together. Long‐term field experiments (LTEs) enable analysis of alternative management practices over time. This study investigated a total of 251 European LTEs in which alternative management practices such as crop rotation, catch crops, cover crops/green manure, no‐tillage, non‐inversion tillage and organic fertilization were applied. Response ratios of indicators for soil quality, climate change and productivity between alternative and reference management practices were derived from a total of 260 publications. Both positive and negative effects of alternative management practices on the different indicators were shown and, as expected, no alternative management practice could comply with all objectives simultaneously. Productivity was hampered by non‐inversion tillage, FYM amendments and incorporation of crop residues. SOC contents were increased significantly following organic fertilizers and non‐inversion tillage. GHG emissions were increased by slurry application and incorporation of crop residues. Our study showed that alternative management practices beneficial to one group of indicators (e.g. organic fertilizers for biological soil quality indicators) are not necessarily beneficial to other indicators (e.g. increase of crop yields). We conclude that LTEs are valuable for finding ways forward in protecting European soils as well as finding evidence‐based alternative management practices for the future; however, experiments should focus more on biological soil quality indicators as well as GHG emissions to enable better evaluation of trade‐offs and mutual benefits of management practices.
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