Jin Liang, Wei Dan, Li Yan, Zou Guoyuan, Wang Lei, Ding Jianli, Zhang Yitao, Sun Lei, Wang Wei, Ma Xingzhu, Shen Huibo, Wang Yuxian, Wang Junqiang, Lu Xinrui, Sun Yu, Ding Xinying, Li Dahao, Yin Dawei
Plant Nutrition and Resources Institute, Beijing Academy of Agriculture and Forestry Sciences, Beijing 100097, China.
Institute of Geographic Sciences and Natural Resources Research, Beijing 100101, China.
Plants (Basel). 2023 Feb 13;12(4):831. doi: 10.3390/plants12040831.
At present, extracting water-soluble organic matter (WSOM) from agricultural organic waste is primarily used to evaluate soil organic matter content in farmland. However, only a few studies have focused on its vertical behavior in the soil profile. This study aims to clarify the three-dimensional fluorescence spectrum characteristics of the WSOM samples in 0-60 cm black soil profile before and after different chemical fertilizer treatments after six years of fertilization. Fluorescence spectroscopy combined with fluorescence and ultraviolet-visible (UV-Vis) spectroscopies are used to divide four different fertilization types: no fertilization (T0), nitrogen phosphorus potassium (NPK) (T1), biochar (T2), biochar + NPK (T3), and biochar + N (T4) in a typical black soil area. The vertical characteristics of WSOC are also analyzed. The results showed that after six years of nitrogen application, T2 had a significant effect on the fluorescence intensity of Zone II (decreasing by 9.6% in the 0-20 cm soil layer) and Zone V (increasing by 8.5% in the 0-20 cm soil layer). The fluorescent components identified in each treatment group include ultraviolet radiation A humic acid-like substances (C1), ultraviolet radiation C humic acid-like substances (C2), and tryptophan-like substance (C3). As compared with the land with T1, the content of C2 in the 20-60 cm soil layer with T2 was lower, while that of C2 in the surface and subsoil with T3 was higher. In addiiton, there were no significant differences in the contents of C1, C2, and C3 by comparing the soils applied with T3 and T4, respectively. The composition of soil WSOM was found to be significantly influenced by the addition of a mixture of biochar and chemical fertilizers. The addition of biochar alone exerted a positive effect on the humification process in the surface soil (0-10 cm). NPK treatment could stimulate biological activity by increasing biological index values in deeper soil layers (40-50 cm). Nitrogen is the sovereign factor that improves the synergism effect of chemical fertilizer and biochar during the humification process. According to the UV-Vis spectrum and optical index, soil WSOM originates from land and microorganisms. This study reveals the dynamics of WSOC in the 0-60 cm soil layer and the biogeochemical effect of BC fertilizer treatment on the agricultural soil ecosystem.
目前,从农业有机废弃物中提取水溶性有机物(WSOM)主要用于评估农田土壤有机质含量。然而,仅有少数研究关注其在土壤剖面中的垂向行为。本研究旨在阐明施肥六年之后,不同化肥处理前后0至60厘米黑土剖面中WSOM样品的三维荧光光谱特征。利用荧光光谱结合荧光和紫外可见(UV-Vis)光谱,在典型黑土区划分出四种不同施肥类型:不施肥(T0)、氮磷钾(NPK)(T1)、生物炭(T2)、生物炭+NPK(T3)以及生物炭+N(T4)。同时分析了水溶性有机碳(WSOC)的垂向特征。结果表明,施氮六年之后,T2对II区(0至20厘米土层荧光强度降低9.6%)和V区(0至20厘米土层荧光强度增加8.5%)的荧光强度有显著影响。各处理组鉴定出的荧光组分包括紫外光A类腐殖酸物质(C1)、紫外光C类腐殖酸物质(C2)以及类色氨酸物质(C3)。与T1处理的土地相比,T2处理的20至60厘米土层中C2含量较低,而T3处理的表层和亚表层土壤中C2含量较高。此外,分别比较T3和T4处理的土壤,C1、C2和C3的含量没有显著差异。发现土壤WSOM的组成受生物炭和化肥混合物添加的显著影响。单独添加生物炭对表层土壤(0至10厘米)的腐殖化过程产生积极影响。NPK处理可通过提高深层土壤(40至50厘米)的生物指数值来刺激生物活性。氮是腐殖化过程中提高化肥与生物炭协同效应的主要因素。根据UV-Vis光谱和光学指数,土壤WSOM源自陆地和微生物。本研究揭示了0至60厘米土层中WSOC的动态变化以及生物炭肥料处理对农业土壤生态系统的生物地球化学效应。
