李廷亮, 谢英荷, 洪坚平, 冯倩, 孙丞鸿, 王志伟. 施磷水平对晋南旱地冬小麦产量及磷素利用的影响[J]. 中国生态农业学报(中英文), 2013, 21(6): 658-665. DOI: 10.3724/SP.J.1011.2013.00658
引用本文: 李廷亮, 谢英荷, 洪坚平, 冯倩, 孙丞鸿, 王志伟. 施磷水平对晋南旱地冬小麦产量及磷素利用的影响[J]. 中国生态农业学报(中英文), 2013, 21(6): 658-665. DOI: 10.3724/SP.J.1011.2013.00658
LI Ting-Liang, XIE Ying-He, HONG Jian-Ping, FENG Qian, SUN Cheng-Hong, WANG Zhi-Wei. Effects of phosphorus application rates on winter wheat yield and phosphorus use efficiency in drylands of South Shanxi Province[J]. Chinese Journal of Eco-Agriculture, 2013, 21(6): 658-665. DOI: 10.3724/SP.J.1011.2013.00658
Citation: LI Ting-Liang, XIE Ying-He, HONG Jian-Ping, FENG Qian, SUN Cheng-Hong, WANG Zhi-Wei. Effects of phosphorus application rates on winter wheat yield and phosphorus use efficiency in drylands of South Shanxi Province[J]. Chinese Journal of Eco-Agriculture, 2013, 21(6): 658-665. DOI: 10.3724/SP.J.1011.2013.00658

施磷水平对晋南旱地冬小麦产量及磷素利用的影响

Effects of phosphorus application rates on winter wheat yield and phosphorus use efficiency in drylands of South Shanxi Province

  • 摘要: 在自然降水条件下, 通过大田试验研究了施磷量对晋南旱地冬小麦部分抗性指标、产量、磷素利用率以及1 m土壤磷素形态分布特征的影响。结果表明: 施磷可以提高旱地冬小麦抗逆性、穗数, 进而提高产量, 但对穗粒数和千粒重影响不明显。在0~120 kg(P2O5)·hm-2施磷范围内, 小麦生育期旗叶硝酸还原酶(NR)活性、穗数和产量随施磷量增加显著增加, 丙二醛(MDA)和脯氨酸(Pro)含量随施磷量增加显著降低。当施磷量达到180 kg(P2O5)·hm-2时, 旗叶中MDA、Pro含量降低幅度较小, 甚至会升高; NR活性除抽穗期外不再有显著变化, 穗数和产量变化亦不显著。磷素施入土壤后易固定, 导致磷肥利用率偏低, 当季回收率仅为9%~13%, 以施磷60~120 kg(P2O5)·hm-2为最高。1 m土壤各土层Hedley形态磷分布特征表现为: HCl-Pi>Residual-P> HCl-Po>NaOH-Pi>NaHCO3-Pi>NaOH-Po>H2O-Pi>NaHCO3-Po>H2O-Po, 其中以HCl-P和Residual-P为主, 分 别占全磷的75%和20%左右, H2O-P、NaHCO3-P和NaOH-P含量共占全磷的5%左右。施入土壤中的磷素当 季主要被固定在0~20 cm土层, 不同Hedley形态磷增加量总体在0~39.11 mg·kg-1之间, 且施磷越多, 被固定磷素就越多。综合考虑冬小麦抗逆性、产量及磷素利用率, 当地旱作冬小麦施磷量(P2O5))以120 kg·hm-2左右为宜。

     

    Abstract: Although rational application of phosphate could increase winter wheat grain yield, phosphate fertilizer can easily be transformed into slowly available or insoluble phosphates in calcareous soils. This could limit phosphorus use efficiency with recovery efficiency of only 5%~25%. It is therefore critical to determine optimal phosphate application rate to enhance high production efficiency and yield of winter wheat. Phosphorus use efficiency is generally affected by several factors including wheat variety, soil fertility and ecological conditions. This implies that results of optimal phosphate application rate could be different in regions with different hydro-climatic and agronomic conditions. In this study, a field experiment was conducted to analyze the effects of phosphate application rates by evaluating selected stress-resistance indexes, including contents of proline (Pro), malondialdehyde (MDA), and nitrate reductase (NR) activity of flag leaf of winter wheat. Winter wheat cultivar "Linhan 6" yield and phosphorus use efficiency were also analyzed along with the distribution of soil phosphorus fractions under four phosphate levels (P2O5 rates of 0 kg·hm-2, 60 kg·hm-2, 120 kg·hm-2, and 180 kg·hm-2) in Xiangfen County. The county is located in the rain-fed cultivation area of Shanxi Province. The study explored suitable phosphate application rate and laid the scientific basis for pro-environmental production of wheat under rain-fed conditions. The results showed that winter wheat stress-resistance strengthened which subsequently increased spike number and yield of winter wheat with increasing phosphate rate. However, no significant difference was observed in kernel number and 1000-kernel weight under different phosphate rates. In the 0~120 kg(P2O5)·hm-2 range, NR activity of flag-leaf, spike number and yield of winter wheat increased significantly. However, MDA and Pro contents of flag-leaf decreased significantly with increasing phosphate rate. When phosphate application rate reached 180 kg(P2O5)·hm-2, MDA and Pro contents slightly decreased, or even increased with increasing phosphate application rate. With the exception of the heading stage, no significant difference was also noted in spike number, yield and NR activity of winter wheat. The phosphate fertilizer use efficiency was relatively low (9%~13%) because of P-fixation. The highest phosphate fertilizer use efficiency was in the application range of 60~120 kg(P2O5)·hm-2. The sequence of phosphate fractions in the 1.0 m soil profile was HCl-Pi > Residual-P > HCl-Po > NaOH-Pi > NaHCO3-Pi > NaOH-Po > H2O-Pi > NaHCO3-Po > H2O-Po. Most of phosphate fractions were HCl-P and Residual-P, accounting for 75% and 20% (in terms of proportion) of soil total phosphate. Also H2O-P, NaHCO3-P and NaOH-P together accounted for 5% of soil total phosphate. The applied phosphorus mainly occurred in the 0~20 cm soil layer during the growth period. The amount of increase in different Hedley phosphorus was 0~39.11 mg·kg-1 and P-fixation increased with increasing phosphate fertilizer rate. Based on a comprehensive stress-resistance index, yield and phosphorus use efficiency, the recommended optimal phosphate application rate was 120 kg(P2O5)·hm-2 in the rain-fed winter wheat conditions in southern Shanxi Province or in drylands with similar ecological conditions.

     

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