Soil Nitrous Oxide Emissions Following Crop Residues Management in Corn-Wheat Rotation Under Conventional and No-Tillage Systems

IF 3.5 Q2 ENVIRONMENTAL SCIENCES
Morad Mirzaei, Manouchehr Gorji Anari, A. Taghizadeh-Toosi, M. Zaman, N. Saronjic, S. Mohammed, S. Szabó, Andrés Caballero-Calvo
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引用次数: 6

Abstract

Agricultural activity is the major anthropogenic source of nitrous oxide (N2O) emissions from terrestrial ecosystems. Conservation agriculture including crop residue management can play a key role in enhancing soil resilience to climate change and mitigating N2O emissions. We investigated the effects of crop residue rates, including 100 % (R100), 50 % (R50), and residue removal (R0), on N2O emissions in corn-wheat rotation under conventional (CT) and no-tillage (NT) systems. The key factors evaluated affecting N2O emissions included soil temperature, soil moisture, soil ammonium, and soil nitrate concentrations. Results showed that the N2O emissions increased with the increasing rate of residue under both CT and NT systems. Both R100 and R50 significantly (p < .05) increased the N2O emissions compared to R0 during the annual rotation cycle. Soil moisture and mineral nitrogen (ammonium and nitrate) were the main driving factors that stimulated N2O emission in both CT and NT systems. In the NT and CT systems, cumulative N2O emissions showed a significant increase with R50 (+75.5 % in NT, +36.5 % in CT) and R100 (+134 % in NT, +40 % in CT) as compared to R0. Furthermore, no significant differences were found between R100 and R50 in the CT system, while in the NT system significant increases were observed for R100 compared to R50. Overall, our study justified as a first approach only during the first year that crop residue removal led to decreased N2O emissions under semi-arid conditions. However, due to the deteriorating impact of crop residue removal on crop productivity and soil C sequestration, this management method cannot be considered a sustainable agronomic practice. We suggest long-term studies to determine the appropriate rate of postharvest crop residue to achieve less N2O emissions and climate-friendly agricultural practices.
常规和免耕制度下玉米-小麦轮作作物残茬管理后土壤氧化亚氮排放
农业活动是陆地生态系统中氧化亚氮(N2O)排放的主要人为来源。包括作物残茬管理在内的保护性农业可以在增强土壤对气候变化的适应能力和减少一氧化二氮排放方面发挥关键作用。研究了常规(CT)和免耕(NT)制度下,100% (R100)、50% (R50)和残茬去除率(R0)对玉米-小麦轮作N2O排放的影响。影响N2O排放的关键因子包括土壤温度、土壤湿度、土壤铵态氮和土壤硝酸盐浓度。结果表明:在CT和NT两种体系下,N2O排放量均随残渣率的增加而增加。与R0相比,R100和R50在年轮作周期内显著(p < 0.05)增加了N2O排放量。土壤水分和矿质氮(铵态氮和硝态氮)是促进旱作系统和旱作系统N2O排放的主要驱动因子。在NT和CT系统中,与R0相比,R50 (NT + 75.5%, CT + 36.5%)和R100 (NT + 134%, CT + 40%)的累积N2O排放量显著增加。此外,R100和R50在CT系统中无显著差异,而在NT系统中R100与R50相比显著升高。总的来说,我们的研究证明,作为第一种方法,在半干旱条件下,只有在第一年去除作物秸秆导致N2O排放减少。然而,由于作物残茬清除对作物生产力和土壤碳固存的影响日益恶化,这种管理方法不能被认为是一种可持续的农艺做法。我们建议进行长期研究,以确定收获后作物残留物的适当比例,以实现减少N2O排放和气候友好型农业实践。
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来源期刊
Air Soil and Water Research
Air Soil and Water Research ENVIRONMENTAL SCIENCES-
CiteScore
7.80
自引率
5.30%
发文量
27
审稿时长
8 weeks
期刊介绍: Air, Soil & Water Research is an open access, peer reviewed international journal covering all areas of research into soil, air and water. The journal looks at each aspect individually, as well as how they interact, with each other and different components of the environment. This includes properties (including physical, chemical, biochemical and biological), analysis, microbiology, chemicals and pollution, consequences for plants and crops, soil hydrology, changes and consequences of change, social issues, and more. The journal welcomes readerships from all fields, but hopes to be particularly profitable to analytical and water chemists and geologists as well as chemical, environmental, petrochemical, water treatment, geophysics and geological engineers. The journal has a multi-disciplinary approach and includes research, results, theory, models, analysis, applications and reviews. Work in lab or field is applicable. Of particular interest are manuscripts relating to environmental concerns. Other possible topics include, but are not limited to: Properties and analysis covering all areas of research into soil, air and water individually as well as how they interact with each other and different components of the environment Soil hydrology and microbiology Changes and consequences of environmental change, chemicals and pollution.
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