蚯蚓与丛枝菌根真菌接种对石漠化土壤碳组分积累与分配的影响

doi:10.13287/j.1001-9332.202408.013

摘要/Abstract

摘要： 探明石漠化土壤碳组分积累和分配对丛枝菌根真菌(AM)与蚯蚓接种的响应,可为提升石漠化土壤固碳潜力及生物修复效率提供数据参考。本研究选择白枪杆为寄主植物,设置接种摩西斗管囊霉(FM)、蚯蚓(E)、蚯蚓+摩西斗管囊霉(E+FM)和不接种(CK)4个处理,研究不同处理土壤碳组分(总有机碳、微生物生物量碳、易氧化有机碳、惰性有机碳)及其分配(微生物生物量碳/总有机碳、易氧化有机碳/总有机碳、惰性有机碳/总有机碳)的时空变化。结果表明: 1)蚯蚓、丛枝菌根真菌单独与共同接种处理均显著促进了土壤碳库各组分积累。与CK相比,接种处理土壤碳组分含量均值的增幅表现为:E+FM>E>FM,接种处理显著促进了土壤微生物生物量碳/总有机碳(30.5%～68.5%)和易氧化有机碳/总有机碳(31.2%～39.2%),但降低惰性有机碳/总有机碳(2.9%～16.2%)。2)不同处理土壤碳组分积累和分配的时空变化存在差异。各碳组分含量最大值均出现在6月,其中E+FM处理各碳组分含量较CK的增幅(33.0%～122.1%)显著高于E(31.2%～95.4%)和FM处理(9.2%～41.3%);微生物生物量碳/总有机碳、易氧化有机碳/总有机碳最大值出现在6月,惰性有机碳/总有机碳最大值则出现在12月,此时3个接种处理各碳组分占有机碳的比例较CK的变幅表现为:E+FM>E>FM;各碳组分含量及其分配均沿土层加深递减(9.7%～146.2%),其中E处理碳组分含量降幅最小,而E+FM处理微生物生物量碳/总有机碳和易氧化有机碳/总有机碳降幅最小、惰性有机碳/总有机碳降幅最大。3) 3个接种处理土壤理化性质变化显著影响各有机碳组分积累及分配,其中碳库组分含量及分配与土壤pH呈极显著负相关,与其他土壤指标呈显著正相关。4)主成分分析显示,土壤含水量、全氮、全磷是影响碳组分积累的主要驱动因子,而土壤含水量、全磷、pH是影响土壤碳组分分配的主控因子。因此,蚯蚓、AM真菌及其交互作用均显著影响石漠化土壤碳组分积累与分配,其影响程度主要取决于土壤含水量、pH及氮磷养分状况。

关键词: AM真菌, 蚯蚓, 碳组分, 碳积累, 碳分配

Abstract: Exploring the responses of carbon component accumulation and allocation to arbuscular mycocorrhizal fungi (AM) and earthworm inoculation can provide reference for improving carbon sequestration potential and bioremediation efficiency in rocky desertification soils. In this study, we chose Fraxinus malacophylla as the host plant to inoculate with Funneliformis mosseae (FM), earthworm (E), and E+FM, using no earthworm and mycorrhizae addition as CK to examine the spatiotemporal variations in soil carbon components (i.e., total organic carbon, microbial biomass carbon, easily oxidized organic carbon, and recalcitrant organic carbon) and their allocation (i.e., microbial biomass carbon/total organic carbon, easily oxidized organic carbon/total organic carbon, and recalcitrant organic carbon/total organic carbon). The results showed that 1) The respective and interactive inoculation of E and AM significantly promoted the accumulation of each carbon component. In contrast with the control, the average carbon component levels under three inoculation treatments were ranked as E+FM>E>FM. The three inoculation treatments significantly promoted soil microbial carbon/total organic carbon (30.5%-68.5%) and easily oxidized carbon/total organic carbon (31.2%-39.2%), but decreased recalcitrant organic carbon/total organic carbon (2.9%-16.2%). 2) The spatiotemporal variation in accumulation and allocation of soil carbon components varied between the inoculation treatments. The maximum value of each carbon component occurred in June. The increase in each carbon component was significantly higher in E+FM (33.0%-122.1%) than that in E (31.2%-95.4%) and FM (9.2%-41.3%). The maximum value of microbial biomass carbon/total organic carbon and easily oxidized organic carbon/total organic carbon was observed in June, while that of recalcitrant organic carbon/total organic carbon was recorded in December. In contrast with CK, the amplitude of variation in the proportion of carbon components in total organic carbon under the three inoculation treatments was ranked as E+FM>E>FM. The accumulation and allocation of all carbon components decreased (9.7%-146.2%) along the soil profile. The level of carbon components in the E treatment decreased the smallest. The microbial biomass carbon/total organic carbon and easily oxidized carbon/total organic carbon decreased the least and the recalcitrant organic carbon/total organic carbon decreased the greatest under the E+FM treatment. 3) Changes in soil physicochemical properties under the three inoculation treatments significantly affected the accumulation and allocation of organic carbon components. Soil pH was negatively correlated with carbon component accumulation and allocation, whereas other soil variables were positively correlated with them. 4) The results of principal component analysis showed that soil water content, total nitrogen, and total phosphorus were the main factors driving carbon component accumulation, while soil water content, total phosphorus, and pH were the main factors controlling carbon component allocation. Therefore, we concluded that the earthworms, AM fungi and their interaction affected the accumulation and allocation of carbon components in Yunnan rocky desertification soils, which would primarily depend on the changes of soil water content, acid-base property, as well as nitrogen and phosphorus conditions.

Key words: arbuscular mycorrhiza, earthworm, carbon component, carbon accumulation, carbon allocation

夏佳慧, 王邵军, 罗双, 李瑞, 杨胜秋, 兰梦杰, 郭晓飞. 蚯蚓与丛枝菌根真菌接种对石漠化土壤碳组分积累与分配的影响[J]. 应用生态学报, 2024, 35(8): 2176-2186.

XIA Jiahui, WANG Shaojun, LUO Shuang, LI Rui, YANG Shengqiu, LAN Mengjie, GUO Xiaofei. Effects of earthworm and arbuscular mycorrhizal fungal inoculation on carbon component accumulation and allocation in rocky desertification soils[J]. Chinese Journal of Applied Ecology, 2024, 35(8): 2176-2186.

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