XU Yanyan, WU Lanfang, LI Binbin, QIU Qingyan, QIN Yue. Soil N2O emission and its agronomic efficiency under different tillage[J]. Chinese Journal of Eco-Agriculture, 2015, 23(11): 1349-1358. DOI: 10.13930/j.cnki.cjea.150373
Citation: XU Yanyan, WU Lanfang, LI Binbin, QIU Qingyan, QIN Yue. Soil N2O emission and its agronomic efficiency under different tillage[J]. Chinese Journal of Eco-Agriculture, 2015, 23(11): 1349-1358. DOI: 10.13930/j.cnki.cjea.150373

Soil N2O emission and its agronomic efficiency under different tillage

  • Cultivated land soil is regarded as an important source of N2O emission that is affected by farming practices. To determine effects of tillage and crop residues management on soil N2O emission and it’s agronomic efficiency on the North China Plain, a field experiment was carried out, which contained 4 treatments with 3 replications. The 4 treatments were conventional tillage with crop residues incorporation to soil (CT+) and without crop residues incorporation to soil (CT), no-tillage with crop residues mulching (NT+) and without crop residues mulching (NT). During the field experimentation soil N2O emissions at soil/atmosphere interface were sampled and analyzed by using static chamber-Gas Chromatography (GC) method in continuous 3 wheat growth seasons; meanwhile, the primary related factors with N2O emission were also investigated and analyzed. The results showed that the dynamic changes of soil N2O emission during wheat growth were similar but the cumulative N2O emissions were significantly different under 4 treatments and, the interactive effect between tillage and crop residues management was significant. The cumulative N2O emission per unit area under CT+ and NT+ were higher than those under CT and NT by 26.2% and 74.6%, respectively, and CT treatment emitted 42.4% more N2O than NT treatment. The soil N2O emission was greatly influenced by soil temperature and soil moisture. The correlation analysis indicated that there was a significant positive correlation between soil N2O emission and both soil temperature at 5 cm depth soil and water filled pore space (WFPS), while there was a significantly negative relation between soil N2O emission and dissolved organic nitrogen (DON). When assessing soil N2O emission in relation to crop productivity expressed as above-ground N uptake (i.e. yield-scaled and nitrogen input-scaled N2O emission), the soil N2O emissions per kilogram grain yield were 0.180.73 g N2O-N and per kilogram nitrogen input were 5.118.0 g N2O-N. Although grain yield and nitrogen productivity were not significantly different among treatments, the N2O emissions in relation to crop productivity were still significantly different among treatments, similar to the N2O emission per unit area that were also greater under CT+ and NT+ than under CT and NT. In conclusion, no-till practice is help to reduce N2O emissions from arable land soil in the North China Plain.
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