温云杰, 张纪涛, 李琳, 王琦, 刁风伟, 高敏, 王秀红, 史向远. 沼液配施化肥对大葱产量和土壤养分、微生物及酶活性的影响[J]. 中国生态农业学报 (中英文), 2024, 32(1): 95−105. DOI:10.12357/cjea.20230401
引用本文: 温云杰, 张纪涛, 李琳, 王琦, 刁风伟, 高敏, 王秀红, 史向远. 沼液配施化肥对大葱产量和土壤养分、微生物及酶活性的影响[J]. 中国生态农业学报 (中英文), 2024, 32(1): 95−105.DOI:10.12357/cjea.20230401
WEN Y J, ZHANG J T, LI L, WANG Q, DIAO F W, GAO M, WANG X H, SHI X Y. Effects of biogas slurry combined with chemical fertilizer on Allium fistulosumyields, soil nutrients, microorganisms, and enzymes activities[J]. Chinese Journal of Eco-Agriculture, 2024, 32(1): 95−105. DOI:10.12357/cjea.20230401
Citation: WEN Y J, ZHANG J T, LI L, WANG Q, DIAO F W, GAO M, WANG X H, SHI X Y. Effects of biogas slurry combined with chemical fertilizer onAllium fistulosumyields, soil nutrients, microorganisms, and enzymes activities[J]. Chinese Journal of Eco-Agriculture, 2024, 32(1): 95−105.DOI:10.12357/cjea.20230401

沼液配施化肥对大葱产量和土壤养分、微生物及酶活性的影响

Effects of biogas slurry combined with chemical fertilizer onAllium fistulosumyields, soil nutrients, microorganisms, and enzymes activities

  • 摘要:明确沼液替代化肥的合适比例以及沼液对大葱产量和土壤养分、微生物含量以及酶活性的影响, 可为沼液的合理施用提供理论依据。试验设计了不施肥(CK)、化肥(CF)、沼液替代25%化肥氮(25BS)、沼液替代50%化肥氮(50BS)、沼液替代75%化肥氮(75BS)、沼液替代100%化肥氮(100BS) 6个处理, 分析了大葱产量及土壤养分含量、磷脂脂肪酸含量和碳氮磷循环相关酶活性, 并通过偏最小二乘法路径模型(PLS-PM)探究上述指标的因果关系。结果表明, 与CK相比, CF和各沼液处理(25BS、50BS、75BS和100BS)均能显著提高大葱产量( P<0.05), 并且大葱产量随沼液替代化肥比例的增加呈先增加后降低趋势, 其中50BS处理的大葱产量最高, 达59.9 t·hm −2。施用沼液可有效改善土壤养分状况, 与CK相比, 施用沼液显著提高土壤有机碳(SOC, 19.5%~65.8%)、全氮(TN, 40.5%~69.6%)、铵态氮(NH 4 +, 26.8%~77.4%)、硝态氮(NO 3 , 30.1%~41.9%)、速效磷(AP, 10.5%~40.6%)、速效钾(AK, 5.4%~8.5%)含量。施用沼液可有效提高土壤微生物含量以及土壤酶活性, 与CK相比, 施用沼液显著提高细菌、真菌、放线菌等微生物的磷脂脂肪酸含量( P<0.05), 降低了革兰氏阳性细菌∶革兰氏阴性细菌的比例( P<0.05), 有助于提高土壤碳、氮、磷相关循环酶活性( P<0.05); 但是, 随着沼液替代比例的增加, 细菌、革兰氏阳性细菌、真菌、总磷脂脂肪酸含量以及碳、氮、磷相关循环酶活性均呈先增加后降低的趋势( P<0.05)。PLS-PM分析表明, 沼液通过增加SOC、TN、NH 4 +、NO 3 、AP含量, 进而提高土壤微生物含量以及碳、氮循环酶活性, 并提升大葱产量, 但是过量的沼液可导致土壤电导率升高, 并对土壤微生物活性和大葱生长产生抑制效果。本研究表明, 短期施用沼液可显著提高大葱产量, 有效改善土壤养分状况, 并有利于土壤微生物含量以及酶活性提高, 其中以沼液替代50%化肥氮的处理效果最优, 但是沼液并不能完全替代化肥, 施用过量的沼液容易造成土壤盐分累积, 不利于大葱和土壤微生物的生长。

    Abstract:The study aimed to determine the optimal ratio of biogas slurry to chemical fertilizer and the effects of biogas slurry combined with chemical fertilizer on Allium fistulosumyields, soil nutrients levels, microorganism contents, and enzyme activities. The field experiment comprised six treatments: no fertilization (CK), chemical fertilizer (CF), 25% substitution inorganic N by biogas slurry N (25BS), 50% substitution inorganic N by biogas slurry N (50BS), 75% substitution inorganic N by biogas slurry N (75BS), and 100% substitution inorganic N by biogas slurry N (100BS). A. fistulosumyields, soil nutrients contents, phospholipid fatty acids (PLFA) contents, and activities of enzymes involved in C, N, and P cycling were investigated. Using the partial least squares path model (PLS-PM), the variations in these parameters to elucidate their internal correlations were explored. The results indicated that CF and biogas slurry (25BS, 50BS, 75BS, and 100BS) treatments significantly increased A. fistulosumyield compared to CK ( P<0.05), with increases of 37.2%, 75.9%, 118.9%, 99.8%, and 59.3%, respectively. Furthermore, as the substitution percentage of inorganic N by biogas slurry N increased, the yields showed a tendency of increasing initially and then decreasing, with the highest yield of 59.9 t·hm −2observed for the 50BS treatment. The application of biogas slurry was effective in improving soil nutrients contents. Compared to CK, the biogas slurry significantly increased the contents of soil organic carbon (SOC), total nitrogen (TN), ammoniacal nitrogen (NH 4 +), nitrate nitrogen (NO 3 ), available phosphorus (AP), and available potassium by 19.5%–65.8%, 40.5%–69.6%, 26.8%–77.4%, 30.1%–41.9%, 10.5%–40.6%, and 5.4%–8.5%, respectively. The application of biogas slurry resulted in a notable enhancement in soil microbial contents and enzymes activities. Compared to CK, the biogas slurry significantly increased the PLFA contents of bacteria, fungi, and actinomycetes ( P<0.05), while concurrently reducing the ratio of gram-positive to gram-negative bacteria. This shift is advantageous for improving the activities of enzymes involved in C, N, and P cycling. However, with an increasing ratio of inorganic N substitution by biogas slurry, the number of bacteria, gram-positive bacteria, fungi, total PLFA content, and enzymes activities involved in C, N, and P cycling exhibited an initial increase followed by a subsequent decrease. The results of PLS-PM indicated that the observed increase in A. fistulosumyields after biogas slurry application could be attributed to the improvements in SOC, TN, NH 4 +, NO 3 and AP contents, microbial contents, and the enhanced activities of enzymes involved in N cycling. Nevertheless, the excessive application of biogas slurry led to elevated soil electrical conductivity (EC), which inhibited microbial activities and ultimately reduced A. fistulosumyields. In conclusion, this study illustrated that the temporary utilization of biogas slurry contributed to the enhancement of A. fistulosumyields, effective improvement of soil nutrient levels, and promotion of soil microbial contents and enzymes activities. Notably, the optimal substitution percentage of inorganic N by biogas slurry was 50% to achieve the highest improvement. However, biogas slurry cannot completely substitute chemical fertilizers because its excessive use may lead to an increase in soil salinity, adversely affecting the growth of A. fistulosumand microorganisms.

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