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退役铀矿区铀富集植物的筛选研究OA

Screening research of uranium concentration plants in decommissioned uranium mine

中文摘要英文摘要

植物修复因其原位修复、易于操作、成本低廉、对环境友好等特点被提出,植物修复技术关键在于筛选适宜的富集植物.通过野外调查与采样、室内盆栽模拟筛选和现场种植实验的方法,对候选植物的铀富集因子(FV)、转运因子(ftr)等进行排序,筛选出铀的富集植物.结果显示,野外调查与采样发现芦苇、苞子草的 FV>1,是可用于铀污染严重地区的生态修复潜在植物;盆栽模拟实验筛选到了 6 种铀富集植物(FV>1),分别是鬼针草、秋葵、牛筋草、龙葵、鸭跖草和黑麦草,反枝苋FV<1,但ftr>1.将筛选出的植物和文献推荐的植物用于现场种植实验,结果表明:牛筋草、苏丹草和芥菜的 FV>1,ftr<1,花生的 FV<1,ftr>1,是可用于铀植物修复研究的候选者.综合三种方法共筛选到 10 种放射性核素铀的富集植物(FV>1),分别是芦苇、苞子草、苏丹草、芥菜、鬼针草、秋葵、牛筋草、龙葵、鸭跖草和黑麦草,未来以期通过基因工程、育种及相关农艺管控等技术提高这 10 种植物和反枝苋、花生的修复潜力.

Phytoremediation has been proposed due to its characteristics such as in-situ remediation,ease of operation,low cost,and environmental friendliness.The key to phytoremediation technology lies in screening suitable hyperaccumulator plants.This study employed methods including field investigation and sampling,indoor potted plant simulation screening,and field planting experiments to rank the uranium concentration factor(FV)and translocation factor(ftr)of candidate plants.The results showed that field investigation and sampling identified Phragmites australis and Themeda caudatahad as having FV>1,making them potential plants for ecological restoration in severely uranium-contaminated areas.The pot experiment screened six uranium hyperaccumulator plants(FV>1),namely Bidens pilosa,Abelmoschus esculentus,Eleusine indica,Solanum nigrum,Commelina communis and Lolium perenne,while Amaranthus retroflexus had FV<1 but ftr>1.The field planting experiment results indicated that Eleusine indica,Sorghum sudanense and Brassica juncea had FV>1 and ftr<1,whereas Arachis hypogaea had FV<1 and ftr>1,making them candidates for uranium phytoremediation research.Combining the three methods,a total of ten hyperaccumulator plants for the radionuclide uranium(FV>1)were identified:Phragmites australis and Themeda caudatahad,Bidens pilosa,Abelmoschus esculentus,Eleusine indica,Solanum nigrum,Commelina communis,Lolium perenne,Sorghum sudanense and Brassica juncea.It is anticipated that future efforts involving genetic engineering,breeding,and related agronomic management techniques will enhance the remediation potential of these ten plants,as well as Amaranthus retroflexus and Arachis hypogaea.

乔新燕;吴仁杰;原寒;王欣妮;冯青靓;张超;贡文静;曹少飞

中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国原子能科学研究院,北京 102413中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006中国辐射防护研究院 中核核环境模拟与评价技术重点实验室,太原 030006

资源环境

铀污染植物修复植物筛选富集因子转运因子

uranium contaminationphytoremediationplant soreeningconcentration factortranslocation factor

《辐射防护》 2026 (1)

37-46,10

国家重点研发计划项目(2020YFC1806603),中国辐射防护研究院自主科研青年基金项目(YQ24000311).

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