| 象草与苦楝/构树间作修复矿区重金属污染土壤潜力 |
| 摘要点击 1338 全文点击 379 投稿时间:2022-03-28 修订日期:2022-04-29 |
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| 中文关键词 间作|重金属|土壤溶液|根际微生物|矿区土壤 |
| 英文关键词 intercropping|heavy metals|soil solution|rhizosphere microorganisms|mining areas |
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| 中文摘要 |
| 为探讨象草与木本植物苦楝/构树间作修复矿区重金属污染土壤潜力,开展室内盆栽试验,分析间作对植物生物量和重金属吸收累积、土壤溶液重金属含量动态变化影响及根际微生物群落组成响应特征.结果表明,和单作相比,象草和苦楝(KX)间作两者地上部生物量分别增加26.5%和13.2%,象草和构树(GX)间作下构树地上部生物量增加13.5%,象草生物量无明显变化.和象草间作后苦楝地上部Cd含量显著提高24.9%,两者地上部Cd和Pb累积量明显提高(P<0.05);间作构树显著增加象草地上部Cd和Pb含量及累积量,但构树地上部Cd和Pb含量明显降低.总体而言,间作处理显著提高单盆植物地上部Cd和Pb共同累积总量,且KX间作下单盆地上部Cd和Pb共同累积总量(1065 μg·pot-1)最高.整个修复期间,KX和GX间作下土壤溶液pH和溶解性有机碳(DOC)含量均高于未修复土壤(CK).修复结束(第150 d)时,KX和GX间作下土壤溶液DOC含量分别较CK显著增加40.5%和33.1%(P<0.05),与CK、象草和构树单作相比,KX间作下土壤溶液Cd含量分别显著降低56.1%、35.5%和46.5%,GX间作下分别显著降低54.5%、33.2%和44.6%(P<0.05).间作下根际土壤微生物香农指数(Shannon)和Chao1指数均显著高于CK,且特有OTUs数量明显高于CK、苦楝和构树单作,放线菌门(Actinobacteriota)和酸杆菌门(Acidobacteriota)等优势细菌丰度增加.与CK、象草和苦楝单作相比,KX间作下放线菌门(Actinobacteriota)丰度分别增加31.6%、20.9%和25.3%,GX间作下分别增加32.3%、21.5%和25.9%.因此,象草和木本植物间作有利于改善土壤环境质量,增加修复植物的地上部生物量及其对Cd和Pb富集,降低土壤重金属迁移风险,尤其是象草和苦楝间作更适于修复矿区多金属污染土壤. |
| 英文摘要 |
| In order to study the potential of intercropping Pennisetum purpureum Schum with Melia azedarach L. and Broussonetia papyrifera for phytoremediation of heavy-metal contaminated soil around mining areas, a pot experiment was conducted to investigate the effects of intercropping on plant biomass, heavy metal accumulation, dynamic changes in heavy metal content in soil solution, and response characteristics of the rhizosphere microbial community. The results indicated that the shoot biomass of P. purpureum and M. azedarach from their intercropping system (KX) was increased by 26.5% and 13.2%, respectively, and the shoot biomass of B. papyrifera from the intercropping system of P. purpureum and B. papyrifera (GX) was increased by 13.5% compared with their corresponding monoculture systems. The shoot Cd content of M. azedarach in the KX treatment was significantly increased by 24.9% (P<0.05), and their Cd and Pb accumulation in shoots were also significantly increased. The shoot contents and accumulations of Cd and Pb from P. purpureum in the GX treatment were significantly increased; however, those in B. papyrifera shoots were decreased. The total accumulations of Cd and Pb in each pot from intercropping systems were higher than that from the monoculture treatment, with that from the KX treatment being the highest at 1065 μg·pot-1. During the 150-day cultivation process, the pH value and dissolved organic carbon (DOC) content in the soil solution under the intercropping systems of KX and GX were higher than those of original soil (CK). After 150 d cultivation, the DOC contents of the soil solution under the KX and GX treatments were significantly increased by 40.5% and 33.1% in comparison with that under CK (P<0.05), respectively. Compared with those from CK and P. purpureum and B. papyrifera monoculture treatments, the Cd content in soil solution from the KX treatment was significantly decreased by 56.1%, 35.5%, and 46.5%, and that in the GX treatment was decreased by 54.5%, 33.2%, and 44.6% (P<0.05), respectively. The Shannon and Chao1 indices of rhizosphere microorganisms under the intercropping systems were significantly higher than those under CK. The number of unique OTUs in intercropping systems was significantly higher than that in CK and the M. azedarach and B. papyrifera monocultures. Intercropping improved the abundance of dominant bacteria such as Actinobacteriota and Acidobacteriota, and the abundance of Actinobacteriota increased by 31.6%, 20.9%, and 25.3% in the KX treatment and by 32.3%, 21.5%, and 25.9% in the GX treatment, respectively, in comparison with those in CK and the P. purpureum and M. azedarach monocultures. It was concluded that intercropping P. purpureum with wood plants could increase their shoot biomass and the accumulations of Cd and Pb, as well as soil environmental quality, whereas the availability and migration risk of heavy metals in soil were reduced. Moreover, the intercropping of P. purpureum and M. azedarach was more beneficial to the remediation of polymetallic-contaminated soil around mining areas. |
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