孙园园, 孙永健, 杨志远, 秦俭, 彭玉, 徐徽, 马均. 不同形态氮肥与结实期水分胁迫对水稻氮素利用及产量的影响[J]. 中国生态农业学报(中英文), 2013, 21(3): 274-281. DOI: 10.3724/SP.J.1011.2013.00274
引用本文: 孙园园, 孙永健, 杨志远, 秦俭, 彭玉, 徐徽, 马均. 不同形态氮肥与结实期水分胁迫对水稻氮素利用及产量的影响[J]. 中国生态农业学报(中英文), 2013, 21(3): 274-281. DOI: 10.3724/SP.J.1011.2013.00274
SUN Yuan-Yuan, SUN Yong-Jian, YANG Zhi-Yuan, QIN Jian, PENG Yu, XU Hui, MA Jun. Nitrogen use efficiency and yield of rice under different nitrogen and water stress conditions at grain-filling stage[J]. Chinese Journal of Eco-Agriculture, 2013, 21(3): 274-281. DOI: 10.3724/SP.J.1011.2013.00274
Citation: SUN Yuan-Yuan, SUN Yong-Jian, YANG Zhi-Yuan, QIN Jian, PENG Yu, XU Hui, MA Jun. Nitrogen use efficiency and yield of rice under different nitrogen and water stress conditions at grain-filling stage[J]. Chinese Journal of Eco-Agriculture, 2013, 21(3): 274-281. DOI: 10.3724/SP.J.1011.2013.00274

不同形态氮肥与结实期水分胁迫对水稻氮素利用及产量的影响

Nitrogen use efficiency and yield of rice under different nitrogen and water stress conditions at grain-filling stage

  • 摘要: 以杂交籼稻"冈优527"和常规粳稻"农垦57"为材料, 设置硫酸铵(铵硝配比100∶0)、硝酸铵(铵硝配比50∶50)、硝酸钠(铵硝配比0∶100)3种形态氮肥及结实期4种水分胁迫处理土壤水势(ψsoil)分别为0 kPa、 25 kPa、 50 kPa、 75 kPa, 持续处理14 d, 研究其对水稻氮素吸收利用及产量的影响。结果表明: 结实期土壤水势在 25 kPa时, 铵硝比50∶50处理较铵硝比100∶0处理的水稻籽粒产量增加显著, 铵态氮比例≥50%时, 适当增加硝态氮比例可缓解土壤水分严重不足对产量形成的不利影响。当土壤水势在0~ 25 kPa范围内适当增加硝态氮肥比例, 有利于促进稻株氮素累积, 尽管与纯铵态氮处理间未达到显著水平, 但与纯硝态氮处理间差异均达到显著水平。土壤水势≤ 50 kPa时, 增加硝态氮产量优势减弱, 相反增加铵态氮肥的比例更有利于产量形成。增加铵态氮有利于分蘖盛期前稻株对氮的吸收, 但在保证一定铵态氮比例下, 适当增加硝态氮有利于加快中、后期对氮素的吸收速度和氮素累积量, 为结实期氮素向籽粒转运及提高氮素利用效率提供保证。适度水分胁迫能促进结实期水稻对氮素的吸收, 促进结实期干物质累积, 提高各器官中营养物质向籽粒运转, 进而有利于收获指数的提高。杂交籼稻"冈优527"和常规粳稻"农垦57"对不同形态氮肥与结实期水分胁迫下氮素利用及产量的响应趋势基本一致。

     

    Abstract: "Gangyou 527" (hybrid indica rice) and "Nongken 57" (conventional japonica) were used to study nitrogen utilization and yield under three nitrogen fertilizers (ammonium sulfate with ammonium/nitrate ratio of 100∶0, ammonium nitrate with ammonium/nitrate ratio of 50∶50 and sodium nitrate with ammonium/nitrate ratio of 0∶100) and four water stress (soil water potential of 0 kPa, 25 kPa, 50 kPa and 75 kPa) treatments for 14 consecutive days at the grain filling stage. The results showed a significantly higher increase in rice grain yield for ammonium/nitrate ratio of 50∶50 than 100∶0 under soil water potential of 25 kPa. When the proportion of ammonium nitrogen was ≥50%, further increase in the proportion of nitrate eased the adverse effects of severe soil moisture shortage on yield formation. Increase in the proportion of nitrate under soil water potential range of 0~ 25 kPa promoted nitrogen accumulation in the rice plant; which significantly different from that of pure nitrate treatment, but not significantly from that of pure ammonium treatment. The advantage of enhanced nitrate was not so obvious when soil water potential ≤ 50 kPa. On the contrary, increased ratio of ammonium greatly enhanced production. Nitrogen absorption by the rice plant before tillering increased with increasing proportion of ammonium nitrogen. However, appropriate increase in nitrate ratio to a certain proportion promoted growth at the mid-late stage of rice. It also enhanced the absorption rate of nitrogen and nitrogen accumulation in seed, which in turn increased nitrogen use efficiency. Moderate water stress promoted seed nitrogen absorption, promoted seed dry matter accumulation, improved grain nutrient content and enhanced grain harvest index. Yield response of hybrid indica rice "Gangyou 527" and conventional japonica rice "Nongken 57" to nitrogen utilization was basically the same under different nitrogen and water stress treatments at the grain-filling stage.

     

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