光伏-蚯蚓模式与有机物料施用对土壤质量的影响

doi:10.13287/j.1001-9332.202504.030

摘要/Abstract

摘要： 为探究蚯蚓和有机物料施用方式对铺设光伏板的坡地土壤质量的影响,探寻推动光伏农业可持续发展与改善土壤质量一体化的新模式,本研究提出了光伏-蚯蚓模式,即在光伏板下的土壤中养殖具有较高药用价值的参状远盲蚓,试验设置光伏板间表施牛粪养殖蚯蚓(Out+S)、光伏板下表施牛粪养殖蚯蚓(In+S)、光伏板间混施牛粪养殖蚯蚓(Out+M)和光伏板下混施牛粪养殖蚯蚓(In+M)共4个处理,以裸地为对照(CK),测定土壤的物理、化学性质以及土壤酶活性。结果表明: Out+M和In+M处理土壤机械稳定性大团聚体、水稳定性大团聚体、有机碳、全氮、碱解氮、速效磷、速效钾含量和酸性磷酸酶活性较CK分别提升了4.7%～18.7%、6.2%～26.0%、37.5%～113.9%、39.4%～90.9%、43.4%～196.8%、222.9%～762.5%、246.1%～460.7%和25.3%～33.3%;光伏板下(In)土壤机械稳定性和水稳定性大团聚体含量较光伏板间(Out)分别提升了13.4%～21.5%和16.1%～16.2%;土壤碱解氮含量、碳氮比和酸性磷酸酶活性分别提升了18.5%～34.1%、13.8%～16.8%和6.3%～36.5%。牛粪混施(M)处理土壤机械稳定性大团聚体、水稳定性大团聚体和粒径≥0.25 mm水稳定性团聚体含量较牛粪表施(S)处理分别提升了6.6%～14.3%、18.5%～18.6%和3.2%～3.8%;有机碳、全氮、碱解氮、速效磷含量、碳氮比和酸性磷酸酶活性分别提升了55.5%～88.2%、37.0%～60.5%、54.4%～74.6%、102.4%～117.8%、13.4%～16.4%和30.7%～67.7%;土壤团聚体破坏率降低了39.0%～50.9%。相关性分析显示,土壤大团聚体与有机碳、土壤养分和酸性磷酸酶呈显著正相关。各处理土壤质量表现为In+M＞Out+M＞In+S＞Out+S>CK。综上,在华南地区坡地光伏农业发展中,In+M对推动当地经济发展、保护生态环境和提升土壤质量有较大的应用潜力。

关键词: 光伏, 蚯蚓, 有机物料, 土壤质量, 农业

Abstract: We investigated the effects of earthworm and organic material application methods on soil quality on slopes where photovoltaic panels are installed, aiming to explore a new model for promoting sustainable development of photovoltaic agriculture and improving soil quality. We proposed the photovoltaic-earthworm model, which involves breeding Amynthas aspergillum with high medicinal value in the soil under photovoltaic panels. There were four treatments: surface application of cow manure between photovoltaic panels to breed earthworms (Out+S), surface application of cow manure under photovoltaic panels to breed earthworms (In+S), mixed application of cow manure between photovoltaic panels to breed earthworms (Out+M), and mixed application of cow manure under photovoltaic panels to breed earthworms (In+M), with the bare land as the control (CK). We measured soil physical and chemical properties, as well as the enzyme activities. The results showed that the content of soil mechanical stability and water stability macroaggregates, organic carbon, total nitrogen, alkaline nitrogen, available phospho-rus, available potassium, and acid phosphatase activity, were significantly enhanced in Out+M and In+M treatments compared to CK by 4.7%-18.7%, 6.2%-26.0%, 37.5%-113.9%, 39.4%-90.9%, 43.4%-196.8%, 222.9%-762.5%, 246.1%-460.7% and 25.3%-33.3%, respectively. The content of soil mechanical stability and water stability macroaggregates under photovoltaic panels (In) was increased by 13.4%-21.5% and 16.1%-16.2%, respectively, compared to between photovoltaic panels (Out). The soil alkaline nitrogen content, carbon nitrogen ratio, and acid phosphatase activity was increased by 18.5%-34.1%, 13.8%-16.8%, and 6.3%-36.5%, respectively. The content of soil mechanically stable macroaggregates, water stable macroaggregates, and water stable macroaggregates with particle size ≥0.25 mm in mixed application of cow manure (M) treatments was increased by 6.6%-14.3%, 18.5%-18.6%, and 3.2%-3.8%, respectively, compared to the surface application of cow manure treatment (S). The content of organic carbon, total nitrogen, alkaline hydrolyzed nitrogen, available phosphorus, carbon nitrogen ratio, and acid phosphatase activity was increased by 55.5%-88.2%, 37.0%-60.5%, 54.4%-74.6%, 102.4%-117.8%, 13.4%-16.4%, and 30.7%-67.7%, respectively. The destruction rate of soil aggregates decreased by 39.0%-50.9%. Soil macroaggregates were significantly positively correlated with organic carbon, soil nutrients, and acid phosphatase. Soil quality of each treatment followed an order of In+M>Out+M>In+S>Out+S>CK. In summary, In+M has the great potential for promoting local economic development, protecting the ecological environment, and improving soil quality in the development of slope photovoltaic agriculture in southern China.

Key words: photovoltaic, earthworm, organic material, soil quality, agriculture

肖远业, 张守涛, 张孟豪, 钟鹤森, 许炜晴, 李馨妤, 毛润乾, 张池. 光伏-蚯蚓模式与有机物料施用对土壤质量的影响[J]. 应用生态学报, 2025, 36(4): 995-1002.

XIAO Yuanye, ZHANG Shoutao, ZHANG Menghao, ZHONG Hesen, XU Weiqing, LI Xinyu, MAO Runqian, ZHANG Chi. Effects of the photovoltaic-earthworm model and organic material application on soil quality[J]. Chinese Journal of Applied Ecology, 2025, 36(4): 995-1002.

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