Impact of reduced tillage on greenhouse gas emissions and soil carbon stocks in an organic grass-clover ley - winter wheat cropping sequence
•First study comparing climate impacts of tillage systems in organic arable farming.•No tillage system impact on N2O and CH4 emissions in grass-clover and wheat.•Higher N2O pulses after tillage operations with increasing soil organic carbon.•Higher soil organic carbon stocks with reduced tillage in...
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| Published in: | Agriculture, ecosystems & environment Vol. 239; pp. 324 - 333 |
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| Main Authors: | , , , , , |
| Format: | Journal Article |
| Language: | English |
| Published: |
Netherlands
Elsevier B.V
15-02-2017
Elsevier BV Elsevier |
| Subjects: | |
| Online Access: | Get full text |
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| Summary: | •First study comparing climate impacts of tillage systems in organic arable farming.•No tillage system impact on N2O and CH4 emissions in grass-clover and wheat.•Higher N2O pulses after tillage operations with increasing soil organic carbon.•Higher soil organic carbon stocks with reduced tillage in slurry fertilised fields.
Organic reduced tillage aims to combine the environmental benefits of organic farming and conservation tillage to increase sustainability and soil quality. In temperate climates, there is currently no knowledge about its impact on greenhouse gas emissions and only little information about soil organic carbon (SOC) stocks in these management systems. We therefore monitored nitrous oxide (N2O) and methane (CH4) fluxes besides SOC stocks for two years in a grass-clover ley – winter wheat – cover crop sequence. The monitoring was undertaken in an organically managed long-term tillage trial on a clay rich soil in Switzerland. Reduced tillage (RT) was compared with ploughing (conventional tillage, CT) in interaction with two fertilisation systems, cattle slurry alone (SL) versus cattle manure compost and slurry (MC). Median N2O and CH4 flux rates were 13μg N2O-Nm−2h−1 and −2μg CH4Cm−2h−1, respectively, with no treatment effects. N2O fluxes correlated positively with nitrate contents, soil temperature, water filled pore space and dissolved organic carbon and negatively with ammonium contents in soil. Pulse emissions after tillage operations and slurry application dominated cumulative gas emissions. N2O emissions after tillage operations correlated with SOC contents and collinearly to microbial biomass. There was no tillage system impact on cumulative N2O emissions in the grass-clover (0.8–0.9kgN2O-Nha−1, 369days) and winter wheat (2.1–3.0kg N2O-Nha−1, 296days) cropping seasons, with a tendency towards higher emissions in MC than SL in winter wheat. Including a tillage induced peak after wheat harvest, a full two year data set showed increased cumulative N2O emissions in RT than CT and in MC than SL. There was no clear treatment influence on cumulative CH4 uptake. Topsoil SOC accumulation (0–0.1m) was still ongoing. SOC stocks were more stratified in RT than CT and in MC than SL. Total SOC stocks (0–0.5m) were higher in RT than CT in SL and similar in MC. Maximum relative SOC stock difference accounted for +8.1MgCha−1 in RT-MC compared to CT-SL after 13 years which dominated over the relative increase in greenhouse gas emissions. Under these site conditions, organic reduced tillage and manure compost application seems to be a viable greenhouse gas mitigation strategy as long as SOC is sequestered. |
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| Bibliography: | ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 |
| ISSN: | 0167-8809 1873-2305 |
| DOI: | 10.1016/j.agee.2017.01.029 |