Strategic tillage achieves lower carbon footprints with higher carbon accumulation and grain yield in a wheat-maize cropping system

Continuous single tillage has the potential to increase greenhouse gas (GHG) emissions and decrease the accumulation of soil organic carbon (SOC), thus increasing carbon footprints (CFs). However, in a wheat-maize cropping system, limited information was available about the effects of strategic till...

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Bibliographic Details
Published in:The Science of the total environment 2021-12, Vol.798, p.149220-149220, Article 149220
Main Authors: Liu, Qiu-Yue, Xu, Cheng-Tang, Han, Shou-Wei, Li, Xiao-Xiao, Kan, Zheng-Rong, Zhao, Xin, Zhang, Hai-Lin
Format: Article
Language:English
Subjects:
Carbon footprints
Carbon storage
Grain yield
Greenhouse gases
Strategic tillage
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Summary:Continuous single tillage has the potential to increase greenhouse gas (GHG) emissions and decrease the accumulation of soil organic carbon (SOC), thus increasing carbon footprints (CFs). However, in a wheat-maize cropping system, limited information was available about the effects of strategic tillage on CFs. Thus, a four-year field experiment was conducted, including continuous rotary tillage (RT), continuous no-till (NT), RT + subsoiling (RS), and NT + subsoiling (NS), to investigate the effects of NS (strategic tillage) on the unit area and unit yield. The results showed that CO2 emission was the highest contributor to CFs (73.92%) in a winter wheat-summer maize cropping system, following the order of NS < NT < RS < RT. The direct N2O emissions from fertilizers and residues were 4.43–4.51 t CO2-eq ha−1 yr−1 during the wheat and maize seasons, and indirect N2O emissions from irrigation and fertilizer inputs had a proportion of >80% from total agricultural inputs. The differences in SOC storage significantly affected the CFs. Although the NS treatment increased the amount of GHG emissions from the residues returned and consumption of diesel, the enhancement of SOC storage by deeper SOC increased. Thus, lower area-scaled CFs were observed in the NS treatment. Furthermore, a higher grain yield and an annual change of SOC storage compared with other treatments were observed under the NS system, which helped to reduce the CFs. The yield-scaled CFs followed the order of RT > RS > NT > NS when considering the changes in SOC storage. Therefore, the NS treatment resulted in a higher grain yield and SOC sequestration with lower CFs, and thus, it could be recommended as the best tillage method to achieve sustainable production and environmental balance in a wheat-maize cropping system. [Display omitted] •Strategic tillage increased the NO2 but reduced the CO2 emissions.•Strategic tillage increased grain yield of wheat and maize.•Strategic tillage enhanced SOC storage in the subsoil.•Strategic tillage decreased area-scaled and yield-scaled CFs for wheat-maize system.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.149220