长期不同施氮量下微生物残体氮对土壤氮库稳定性和玉米氮素吸收的影响

Impact of microbial residue nitrogen on soil nitrogen pool stability and maize nitrogen uptake under long-term varying nitrogen applications

  • 摘要: 在农田生态系统中, 化肥氮的施用是保障粮食高产稳产并维持土壤氮库稳定的重要管理措施, 土壤微生物既是土壤氮素矿化的驱动者, 也是土壤氮素固持的贡献者, 在氮素保蓄和供应方面发挥着积极作用, 直接影响作物的氮素吸收利用。本研究依托中国科学院栾城农业生态系统试验站小麦-玉米轮作农田14年长期不同施氮水平定位试验, 选取玉米季施氮量150 kg(N)∙hm−2 (N150)、200 kg(N)∙hm−2 (N200)和300 kg(N)∙hm−2 (N300) 3个典型处理, 通过微区施用15N标记氮肥, 在收获期测定玉米产量、地上部总吸氮量和肥料氮吸收量, 分析0~20 cm土层土壤全氮(TN)、微生物残体氮MRN, 包括真菌残体氮(FRN)和细菌残体氮(BRN)、固定态铵(FN)、矿质氮(NH4+-N+NO3-N, MN)和其他有机氮(ON)含量及不同氮库对15N的截获, 并通过多元回归分析和路径分析建立各形态氮库与玉米氮素吸收的相关关系, 研究土壤“老氮”和肥料“新氮”在土壤氮库中的分配及其对作物吸收利用的影响, 为研究区氮肥高效利用和地力培肥提供理论支撑。结果表明, 玉米产量和氮素吸收以及土壤TN含量均以N200最高, 此施氮量有利于作物高产和土壤氮库培育。N300的肥料氮吸收和残留量高于N200, 表明N300的土壤氮“激发效应”强于N200, 会诱导土壤“老氮”的更多矿化和损失, 其土壤TN库稳定性差、更新程度较大。总氮库中, MRN占主导, N200显著高于其他处理, 对TN的贡献均在50%以上, 且FRN主导了MRN的累积。N200的土壤FRN∶BRN比值显著高于N150和N300, 表明适宜施氮可显著提升真菌在氮素积累中的贡献, 提升土壤氮库的稳定性; 施氮不足(N150)或过量施氮(N300)提升了细菌在氮素积累中的贡献, 不利于稳定土壤氮库。N300的MN和FN含量显著高于其他处理, 表明过量施肥更多提升的是活性氮库。由此可见, 适宜施氮可优化土壤氮库分配, 促进更多的氮进入微生物残体氮库, 显著提高土壤微生物途径对氮的固持作用, 促进土壤对氮素的保蓄与供应良性运行, 保障了玉米氮素吸收与产量形成, 为指导华北平原农田地力培肥与氮肥减施提供了科学依据。

     

    Abstract: In farmland ecosystems, the application of chemical nitrogen (N) fertilizers is a crucial management strategy to ensure stable and high grain yields while maintaining the stability of soil N pools. Soil microorganisms play a pivotal role in both N mineralization and immobilization, thereby actively contributing to N retention and supply, which directly affects N uptake and utilization by crops. This study was conducted in the wheat-maize rotation field of the Luancheng Agro-Ecosystem Experimental Station of the Chinese Academy of Sciences. This study relied on a 14-year long-term positioning experiment with different N application rates. Three typical treatments were selected for N application rates during the maize season: 150 kg(N)∙hm−2 (N150), 200 kg(N)∙hm−2 (N200), and 300 kg(N)∙hm−2 (N300). Micro-plots were used to apply 15N-labeled N fertilizer to investigate the distribution of “old N” from soil and “new N” from fertilizer within soil N pools and their impact on crop N uptake and utilization. At harvest, the maize yield, total N uptake by the aboveground parts, and N uptake from fertilizers were measured. The contents of total N (TN), microbial residue N (MRN), fixed ammonium (FN), mineral N (NH4+-N + NO3-N, MN), and other organic N (ON) in the 0−20 cm soil layer were analyzed, along with the interception of 15N by different N pools. Multivariate regression and path analyses were used to establish the relationships between various N pool forms and maize N uptake. The results indicated that maize yield, N uptake, and soil TN content were the highest under the N200 treatment, favoring high crop yields and soil N pool cultivation. Fertilizer N uptake and residue were higher under the N300 treatment than under the N200 treatment, suggesting a stronger “priming effect” under the N300 treatment, which induces greater mineralization and loss of soil “old N”. The stability of soil TN pool was poor under the N300 treatment, with a higher degree of turnover. Among the TN pools, MRN was dominant, with the N200 treatment being significantly higher than N150 treatment, contributing more than 50% of the TN. Fungal residue N (FRN) was the main contributor to MRN accumulation. The ratio of FRN to bacterial residual N (BRN) was higher in the N200 treatment than in the N150 and N300 treatments, indicating that optimal N application could significantly enhance the contribution of fungi to N accumulation, thereby improving the stability of the soil N pool. Insufficient N application (N150) or excessive N application (N300) increased the contribution of bacteria to N accumulation, which was not conducive to stabilizing the soil N pool. The MN and FN contents were significantly higher in the N300 treatment than in other treatments, suggesting that excessive fertilization predominantly enhanced the active N pool. In conclusion, optimal N application can optimize the soil N pool distribution, promote the sequestration of N into microbial residue pools, significantly enhance the N immobilization capacity of soil microorganisms, and foster the benign operation of soil N retention and supply. This ensures maize N uptake and yield. The study provides a scientific basis for guiding farmland fertility improvement and N fertilizer reduction in the North China Plain.

     

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