AI Article Synopsis
- Excessive nitrogen application in wheat-maize farming can be improved through sustainable practices that reduce nitrogen losses and maintain crop yield.
- Adjusted nitrogen practices, especially optimized treatments with controlled release urea, showed increased crop yields and nitrogen use efficiency compared to traditional high-application methods.
- These sustainable practices also significantly decreased hydrological nitrogen losses, highlighting the importance of nitrogen management in agriculture.
Article Abstract
Excessive nitrogen (N) application in wheat-maize cropping systems was adjusted towards more sustainable practices to reduce hydrological N losses while maintaining crop yield. In comprehensive quantification of N management effects on crop yield, N use efficiency (NUE), hydrological N losses, and soil nitrate residual across eight seasons, we have added to growing evidence of strategies beneficial for sustainable crop production with lower hydrological N losses. The results show that adjusted N practices enhanced crop yield and NUE, as compared to farmer's practices, but benefits varied with N rates and types. Optimized N treatment (OPT, 180 kg N ha in both maize and wheat seasons) with or without straw returning produced the most crop yield. They increased maize yield by 5.5% and 7.3% and wheat yield by 6.2% and 3.2% on average, as compared to farmer's practice with huge N application (FP, 345 kg N ha and 240 kg N ha in maize and wheat). Regulation of N release through amendment with controlled release urea at a rate of 144 kg N ha crop (CRU treatment) obtained 4.4% greater maize yield than FP, and sustained a similar wheat yield with less N input, resulting in the highest crop NUE. Additionally, CRU was most effective in mitigating hydrological N loss, with 39.5% and 45.5% less leachate N and 31.9% and 35.9% less runoff N loss than FP in maize and wheat seasons. Synthetic N input correlated significantly and positively with runoff and leachate N losses, indicating it was one of the dominant factors driving hydrological N losses. Moreover, compared to OPT, additional straw returning (STR) or substituting 20% of the nutrients by duck manure (DMS) further reduced runoff N discharges due to the fact that organic matter incorporation increased resilience to rainfall. N over-application in FP caused considerable nitrate accumulation in the 0-90-cm soil profile, while the adjusted N practices, i.e., OPT, STR, CRU, and DMS treatments effectively controlled it to a range of 79.6-92.9 kg N ha. This study suggests that efforts using optimized N treatment integrated with CRU or straw returning should be encouraged for sustainable crop production in this region.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10682078 | PMC |
| http://dx.doi.org/10.3389/fpls.2023.1274943 | DOI Listing |
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