水氮组合对冬小麦干物质及氮素积累和产量的影响

于2015—2017年小麦生长季在山东省泰安市农业科学研究院肥城试验基地进行田间试验,供试材料为‘泰山28',在150(A₁)、300(A₂)、450(A₃)、600 m³·hm^-2(A₄)4个灌水量和90(B₁)、135(B₂)、180(B₃)、225 kg·hm^-2(B₄)4个施氮水平下,研究水氮组合对小麦生长发育过程中干物质积累、氮素积累、水分消耗利用、光合特性、籽粒产量等的影响。结果表明: A₃B₃条件下各生育阶段的干物质积累量和氮素积累量,成熟期籽粒干物质和氮素积累量均为最大,花前花后营养器官生产储藏干物质及氮素向籽粒的运输量最高,且与其他水氮组合处理差异显著。各氮素处理下,60~200 cm土层土壤耗水量均为A₃>A₄>A₂>A₁;A₃B₃处理下的水分利用效率和氮素利用效率高于A₃B₄、A₄B₃和A₄B₄。A₃B₃处理显著提高了开花后7~28 d的旗叶净光合速率、气孔导度和蒸腾速率,有利于小麦进行光合作用合成碳水化合物。水氮组合效应显著影响籽粒产量和产量构成,且A₃B₃处理下小麦产量最高,达到9400 kg·hm^-2。综上,450 m³·hm^-2和180 kg·hm^-2的水氮组合处理可以显著提高小麦干物质和氮素积累量,并促进干物质和氮素向籽粒运输,与高水肥处理相比,可以有效提高水分利用效率和氮素利用效率,有利于增强小麦旗叶的光合能力,产生更多的碳水化合物,增加籽粒产量。

Effects of water-nitrogen combination on dry matter,nitrogen accumulation and yield of winter wheat

In two growing seasons of wheat (2015-2017), we conducted a field trial with Taishan 28 in Tai'an Academy of Agricultural Science Feicheng experimental base, Tai'an City, Shandong Province. There were four irrigation levels of 150 (A₁), 300 (A₂), 450 (A₃), and 600 (A₄) m³·hm^-2, and four nitrogen application levels of 90 (B₁), 135 (B₂), 180 (B₃), and 225 (B₄) kg·hm^-2. We examined the effects of the combination effects of irrigation and nitrogen on dry matter accumulation and transport, nitrogen accumulation and transport, water consumption and utilization, photosynthetic characteristics, wheat grain yield and yield components of wheat. The results showed that dry matter accumulation, nitrogen accumulation, vegetative organs production, storage and the transportation volume to grains of the dry matter and nitrogen, and dry matter and nitrogen accumulation of grain in the mature stage of wheat all reached the maximum in A₃B₃ treatment, which were significantly different from other treatments. Under all the nitrogen treatments, soil water consumption in the 60-200 cm soil layer was A₃>A₄>A₂>A₁. Water use efficiency and nitrogen use efficiency in A₃B₃ treatment were higher than that under A₃B₄, A₄B₃ and A₄B₄. The net photosynthetic rate, stomatal conductance and transpiration rate of flag leaves from 7 to 28 days after flowe-ring were all significantly higher in A₃B₃ treatment, which was conducive to the photosynthetic synthesis of carbohydrates in wheat. The interaction effect of water and nitrogen addition significantly affected grain yield and yield components. Wheat yield was the highest in A₃B₃ treatment which reached at 9400 kg·hm^-2. In conclusion, the treatment with irrigation of 450 m³·hm^-2 and nitrogen of 180 kg·hm^-2 could significantly improve dry matter and nitrogen accumulation, and promote transportation volume of the dry matter and nitrogen to grain. Compared with the high water and nitrogen treatment, it could effectively increase water use efficiency and nitrogen use efficiency, enhance photosynthetic capacity of flag leaf, produce more carbohydrate, and increase grain yield.