Does a trade-off between yield and efficiency reduce water and nitrogen inputs of winter wheat in the North China Plain?

摘要

Increasing both grain yield and water use efficiency (WUE)/nitrogen partial factor productivity (NPFP) of winter wheat is crucial to realize the sustainable development of agricultural production in the North China Plain (NCP). This study was conducted to test the hypothesis that a trade-off between yield and efficiency could reduce water and nitrogen inputs of winter wheat in the NCP. Wheat yield, WUE and NPFP under three production levels, i.e. the potential, high-yield and high-efficiency (HH), and on-farm, and their gaps were investigated with APSIM-Wheat model. The results showed that simulated potential yields were close to observed potential yields with RMSE of 1150 kg ha(-1) (NRMSE of 12 %) and simulated on-farm yields followed with observed yields with RMSE of 576 kg ha(-1) (NRMSE of 8.8 %). Simulated yield gap between the potential and on-farm yields was 2565 kg ha(-1) averaged across the NCP from 1981 to 2015 with the highest yield gap in the central part of NCP and the eastern Shandong province, and the corresponding gaps of WUE and NPFP were 0.45 kg m(-3) and 10.9 kg N kg(-1) with a large spatial difference. To narrow the gaps, about 33 mm additional irrigation and 5 kg N ha(-1) reductions from the current irrigation (242 mm) and N fertilizer (267 kg N ha(-1)) application amounts were needed across the NCP. WUE and NPFP could be increased by 29 % and 43 % from the on-farm to the potential levels. However, if on-farm yield only attained 80 % of the potential, WUE and NPFP could be increased by 0.96 kg m(-3) (60 %) and 19.3 kg kg(-1) (77 %) across the NCP. Irrigation and nitrogen fertilization amounts could be reduced by averaged 127 mm and 89 kg ha(-1) from current averaged irrigation and nitrogen fertilization amounts across the NCP. Especially, the irrigation schedule at on-farm level should be adjusted from three or four irrigations at (sowing), overwintering, jointing and flowering to two irrigations at jointing and flowering across the NCP. Our results suggested an explicit potential for wheat yield and water-nitrogen efficiency win-win by optimizing water and nitrogen management in the NCP.