Yin Qiuling, Lyu Peng, Wang Guanghui, Wang Bing, Li Yingjie, Zhou Zhongkui, Guo Yadan, Li Lianfang, Deng Nansheng
School of Water Resources & Environmental Engineering, East China University of Technology, Nanchang 330013, China.
Key Laboratory of Agro-Environment, Ministry of Agriculture, Beijing 100101, China; Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences, Beijing 100081, China.
Ecotoxicol Environ Saf. 2022 Apr 1;234:113363. doi: 10.1016/j.ecoenv.2022.113363. Epub 2022 Mar 3.
The decommissioning of uranium tailings (UMT) is usually accompanied by uranium (U) contamination in soil, which poses a serious threat to human health and ecological security. Therefore, the remediation of uranium pollution in soil is imminent from ecological and environmental points of view. In recent years, the use of biochar stabilizers to repair uranium tailings (UMT) soil has become a research hotspot. In this study, a novel phosphorus-modified bamboo biochar (PBC) cross-linked Mg-Al layered double-hydroxide composite (PBC@LDH) was prepared. The hyperaccumulator plant Indian mustard (Brassica juncea L.) was selected as the test plant for outdoor pot experiments, and the stabilizers were added to the UMT soil at the dosage ratio of 15 g kg, which verified the bioconcentrate and translocate of U and associated heavy metal Pb in the UMT soil by Indian mustard after stabilizer remediated. The results shown that, after 50 days of growth, compared with the untreated sample (CK), the Indian mustard in PBC@LDH treatment possessed a better growth and its biomass weight of whole plant was increased by 52.7%. Meanwhile, the bioconcentration factors (BF) of U and Pb for PBC@LDH treatment were significantly decreased by 73.4% and 34.2%, respectively; and the translocation factors (TF) were also commendable reduced by 15.1% and 2.4%, respectively. Furthermore, the Tessier available forms of U and Pb in rhizosphere soil showed a remarkably decrease compared with CK, which reached by 55.97% and 14.1% after PBC@LDH stabilization, respectively. Complexation, precipitation, and reduction of functional groups released by PBC@LDH with U and Pb described the immobilization mechanisms of biochar stabilizer preventing U and Pb enrichment in Indian mustard. As well as, the formation of U-containing vesicles was prevented by the precipitation of -OH functional groups with free U and Pb ions around the cell tissue fluids and vascular bundle structure of plant roots, thereby reducing the migration risk of toxic heavy metals to above-ground parts. In conclusion, this research demonstrates that the PBC@LDH stabilizer offers a potentially effective amendment for the remediation of U contaminated soil.
铀尾矿退役通常伴随着土壤中的铀污染,这对人类健康和生态安全构成严重威胁。因此,从生态和环境角度来看,修复土壤中的铀污染迫在眉睫。近年来,利用生物炭稳定剂修复铀尾矿土壤已成为研究热点。本研究制备了一种新型磷改性竹生物炭(PBC)交联Mg-Al层状双氢氧化物复合材料(PBC@LDH)。选择超富集植物印度芥菜(Brassica juncea L.)作为室外盆栽试验的受试植物,并以15 g/kg的剂量比将稳定剂添加到铀尾矿土壤中,验证了稳定剂修复后印度芥菜对铀尾矿土壤中铀及相关重金属铅的生物富集和转运情况。结果表明,生长50天后,与未处理样品(CK)相比,PBC@LDH处理的印度芥菜生长较好,全株生物量增加了52.7%。同时,PBC@LDH处理的铀和铅的生物富集系数(BF)分别显著降低了73.4%和34.2%;转运系数(TF)也分别值得称赞地降低了15.1%和2.4%。此外,根际土壤中铀和铅的Tessier有效形态与CK相比显著降低,PBC@LDH稳定后分别达到55.97%和14.1%。PBC@LDH释放的官能团与铀和铅的络合、沉淀和还原描述了生物炭稳定剂防止铀和铅在印度芥菜中富集的固定机制。此外,通过植物根细胞组织液和维管束结构周围的-OH官能团与游离铀和铅离子的沉淀,防止了含铀囊泡的形成,从而降低了有毒重金属向地上部分迁移的风险。总之,本研究表明PBC@LDH稳定剂为修复铀污染土壤提供了一种潜在有效的改良剂。
