增施铵态氮肥诱导滨海盐渍土作物根际降碱抑钠可实现以种适地增产增效

Induced decline of alkali and sodium content in the rhizosphere by applying ammonium containing fertilization can increase the adaptation and yield of crops to salt-affected soil

  • 摘要: 通过改变栽培种植模式激发作物自身抗盐碱的潜力, 实现作物以种适地增产增效目标, 对盐碱地绿色产能提升具有重要意义。本试验以滨海盐渍土冬小麦-夏玉米轮作体系为研究对象, 采用田间定位试验, 设置AS0 (100%尿素, 磷肥减量)、AS50 (50%尿素+50%硫酸铵, 磷肥减量)、AS75 (25%尿素+75%硫酸铵, 磷肥减量)、AS100 (100%硫酸铵, 磷肥减量)和FP (农民过量施氮磷肥, 100%尿素, 对照1)、P0 (不施磷肥, 100%尿素, 对照2) 6个处理, 分析了不同硫酸铵替代尿素比例处理条件下冬小麦和夏玉米的产量、养分吸收量、氮磷肥利用效率、根际土壤pH、根际土壤盐度和钠吸附比(Sodium adsorption ratio, SAR)的变化。2年田间试验结果表明: 盐碱地上P0处理的小麦、玉米产量最低, 作物生长受到土壤缺磷限制; 与FP处理相比, 所有减磷处理的作物产量无显著差异。等氮等磷条件下, 与全部施用尿素(AS0)处理相比, AS50处理冬小麦平均增产5.4%; 夏玉米平均增产1.5%。增施硫酸铵(AS50、AS75、AS100)处理与AS0处理相比小麦根际土壤pH降低0.08~0.24个单位, 玉米根际pH降低0.06~0.35个单位。随硫酸铵比例增加, 根际土壤速效磷含量呈现先增后减的趋势, 其中AS50处理速效磷含量最高; 根际土壤Ca2+、Na+含量和SAR降低。与FP处理相比, AS50和AS75处理的根际pH值、SAR和Na+含量均显著降低, 氮磷肥利用效率显著提高。并且, 玉米季的处理效应比小麦季更显著。在滨海盐渍土区, 与FP处理相比, 硫酸铵替代50%的尿素能够在磷肥减施的情况下通过诱导根际pH的下降促进SAR和Na+含量降低、提高有效磷和Ca2+含量, 营造更适宜作物生长的根际低盐低碱高营养环境, 从而提高产量和肥料利用效率。基于以上结果提出了增铵降碱解磷增钙的措施, 诱导根土界面肥盐分布区隔化、实现以种适地的轻-中度盐碱地作物增产增效。

     

    Abstract: It is of great significance to improve the green productivity of saline-alkali soil by changing the cultivation mode to stimulate the potential of crop resistance to salt and alkali, and achieve the goal of increasing the yield and efficiency of crops by planting suitable soil. In this experiment, the winter wheat-summer maize rotation system in coastal saline-alkali land was used as the research object. Using the field positioning experiment, the treatment includes the following six: AS0 (100% urea, phosphorus fertilizer reduction), AS50 (50% urea +50% ammonium sulfate, phosphorus fertilizer reduction), AS75 (25% urea +75% ammonium sulfate, phosphorus fertilizer reduction), AS50 (100% ammonium sulfate, phosphorus fertilizer reduction), FP (farmers over fertilization, 100% urea, control 1) and P0 (no phosphorus fertilizer, 100% urea, control 2). The changes in yield, nutrient uptake, nitrogen and phosphorus fertilizer utilization efficiency, and rhizosphere soil pH, salinity and sodium adsorption ratio (SAR) of winter wheat and summer maize were analyzed under different ammonium sulfate replacement urea ratio treatments. The results of the 2-year field experiment showed that the yields of wheat and maize treated with P0 were the lowest, indicating that the soil lacked phosphorus. There was no significant difference in yield between all phosphorus reduction treatments and FP treatment. Under the condition of iso-nitrogen and phosphorus, the AS50 treatment resulted in an average yield increase of 5.4% for winter wheat and 1.5% for summer maize compared to AS0. Compared with AS0 treatment, increased application of ammonium sulfate (AS50, AS75, AS100) reduced the pH of wheat rhizosphere soil by 0.08 to 0.24 units, and the pH of corn rhizosphere soil by 0.06 to 0.35 units. With the increase of ammonium sulfate ratio, the content of available phosphorus in rhizosphere soil increased first and then decreased, and the content of available phosphorus in AS50 treatment was the highest. The content of Ca2+, Na+ and SAR in rhizosphere soil decreased. Compared with FP treatment, rhizosphere pH, SAR and Na+ contents of AS50 and AS75 treatment were significantly reduced, and nitrogen and phosphorus fertilizer utilization efficiency were significantly improved. Moreover, the treatment effect of maize season was more significant than that of wheat season. In coastal saline-alkali cultivated lands, compared to the FP treatment, substituting 50% of urea with ammonium sulfate under reduced phosphorus application can promote the reduction of SAR and Na+ content and the increase of available phosphorus and Ca2+ content by inducing a decrease in rhizosphere pH. This created a more suitable rhizosphere environment with lower salt, lower alkali, and higher nutrient content for crops, thereby enhancing yield and fertilizer utilization efficiency. Based on the above understanding, the technical principle of adding ammonium, reducing alkali, mobilizing phosphorus and increasing calcium to induce the separation of fertilizer and salt distribution at the root-soil interface was put forward to achieve the increase of crop yield and efficiency in light to medium saline-alkali soil.

     

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