于晓芳, 雷娟玮, 高聚林, 马达灵, 王志刚, 胡树平, 孙继颖, 青格尔, 屈佳伟, 王富贵. 提升土壤肥力可实现玉米机械粒收增产减损[J]. 中国生态农业学报(中英文), 2021, 29(6): 1061-1075. DOI: 10.13930/j.cnki.cjea.200695
引用本文: 于晓芳, 雷娟玮, 高聚林, 马达灵, 王志刚, 胡树平, 孙继颖, 青格尔, 屈佳伟, 王富贵. 提升土壤肥力可实现玉米机械粒收增产减损[J]. 中国生态农业学报(中英文), 2021, 29(6): 1061-1075. DOI: 10.13930/j.cnki.cjea.200695
YU Xiaofang, LEI Juanwei, GAO Julin, MA Daling, WANG Zhigang, HU Shuping, SUN Jiying, Qing geer, QU Jiawei, WANG Fugui. Soil fertility improvement increases maize yield and reduces loss during mechanized grain harvest[J]. Chinese Journal of Eco-Agriculture, 2021, 29(6): 1061-1075. DOI: 10.13930/j.cnki.cjea.200695
Citation: YU Xiaofang, LEI Juanwei, GAO Julin, MA Daling, WANG Zhigang, HU Shuping, SUN Jiying, Qing geer, QU Jiawei, WANG Fugui. Soil fertility improvement increases maize yield and reduces loss during mechanized grain harvest[J]. Chinese Journal of Eco-Agriculture, 2021, 29(6): 1061-1075. DOI: 10.13930/j.cnki.cjea.200695

提升土壤肥力可实现玉米机械粒收增产减损

Soil fertility improvement increases maize yield and reduces loss during mechanized grain harvest

  • 摘要: 针对我国玉米生产中机械粒收存在产量损失率、破碎率高的问题,本试验以农户浅旋的土壤肥力为对照,设置深耕、免耕和秸秆原位还田措施等创造的不同土壤肥力水平,以‘先玉696’和‘西蒙6号’为试验材料,在高低两种种植密度下测定玉米机收质量、穗位整齐度、倒伏率、籽粒脱水速率和籽粒含水率,以及产量和产量构成等指标,揭示土壤肥力提升后对玉米机械粒收增产减损的影响机制。研究结果表明:1)提升土壤肥力可降低玉米机械粒收的产量损失率,在高密度下作用更加明显,每提升1个肥力单位,产量损失率下降12.55~15.70个百分点。2)提升土壤肥力可以使穗位整齐度提高5.35~9.69、玉米倒伏率降低5.44~9.75个百分点、籽粒平均脱水速率提高0.048~0.090%·d-1,有效缓解增密带来的负面影响,是产量损失率降低的主要原因。3)提高土壤肥力可明显增加玉米的有效穗数、穗粒数和千粒重,从而使玉米籽粒产量提高1878.5~2544.4 kg·hm-2;增密后高肥力水平土壤具有增产效果。因此,内蒙古地区通过耕作措施与秸秆还田提升土壤肥力可实现玉米机械粒收增产减损。

     

    Abstract: The rates of maize grain yield loss, grain crushing, and impurity during mechanized grain harvest in China are high. To reduce grain yield loss, the effects of soil fertility improvement on mechanized grain harvest quality were investigated to provide a theoretical basis for optimizing tillage and straw returning measures. Maize cultivars 'XY696' and 'XM6' were planted at high and low densities under different soil fertilities: low fertility (with tillage and straw returning measures of strip cultivation and no-tillage), medium fertility (with subsoiling and deep tillage), and high fertility (with straw incorporation, subsoiling, and straw incorporation with deep tillage). The farm rotary tillage (with much lower fertility) served as the control treatment. The following mechanized grain harvest quality indicators were measured: ear height uniformity, lodging rate, dehydration rate, and grain moisture content, as well as the yield and yield components. The results showed that soil fertility, maize cultivar, and planting density significantly (P < 0.05) affected the quality indexes of mechanized grain harvest, maize morphology characteristics, grain dehydration, and maize yield. Soil fertility improvement reduced grain yield loss during maize mechanized grain harvest, whereas the grain crushing and impurity rates did not change with soil fertility improvement. Under high planting density, yield loss decreased by 12.55-15.70 percentage for each fertility unit. Yield loss increased with increasing planting density, and the loss rate of 'XY696' was more than that of 'XM6'. Soil fertility improvement led to an increase in ear height uniformity (5.35-9.69), reduced maize lodging (5.44-9.75 percentage), and increased the grain dehydration rate (0.048-0.090%·d-1). Optimization of these indexes may explain the reduction in yield loss at high fertility. Increased planting density reduced ear height uniformity and increased the maize lodging and grain dehydration rates. Soil fertility improvement effectively alleviated the negative impacts of densification. 'XY696' had lower ear height uniformity, higher lodging, and slower dehydration compared to 'XM6', which led to higher grain loss for 'XY696'. Soil fertility improvement increased the ear numbers per unit area, grain numbers per ear, and 1000-grain weight, ultimately increasing yield by 1878.5-2544.4 kg·hm-2 for each fertility unit increase. The increase in maize grain yield was due to a reduction in grain yield loss during mechanized maize grain harvest. The number of ears per unit area increased, whereas the grain number per ear and the 1000-grain weight decreased when the planting density increased. Maize grain yield increased when the planting density increased at high fertility levels. Therefore, soil fertility improvement via tillage and straw returning can increase maize yield and reduce yield loss during mechanized grain harvest in Inner Mongolia. Under high soil fertility, a reasonable planting density increase can improve the yield and harvest quality and decrease the grain moisture content. Reduced mechanized grain loss can be achieved by selecting maize cultivars with high lodging resistance, high ear height uniformity, and a fast dehydration rate.

     

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