Research Progress of Microbial Technology in Utilization of Rare Earth Resources

被引：0

作者：

Tu Z. ^{[1
,2
]}

Xiao Q. ^{[1
]}

Zhang X. ^{[1
]}

Liu J. ^{[1
,3
]}

He H. ^{[1
,4
]}

Liu C. ^{[1
,4
]}

Song B. ^{[1
,4
]}

机构：

[1] School of Environmental Science and Engineering, Guilin University of Technology, Guilin

[2] Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, Guangzhou

[3] Collaborative Innovation Center for Water Pollution Control and Water Safety Assurance in Karst Areas of Guilin University of Technology, Guilin

[4] Guangxi Key Laboratory of Environmental Pollution Control Theory and Technology, Guilin Universi⁃ ty of Technology, Guilin

来源：

Zhongguo Xitu Xuebao/Journal of the Chinese Rare Earth Society | 2024年 / 42卷 / 03期

关键词：

bioconcentration; bioleaching; microbial technology; rare earth resources;

D O I：

10.11785/S1000-4343.20240305

中图分类号：

学科分类号：

摘要：

Rare earths are non-renewable and valuable resources that are widely used in production and life. In view of the current situation of extensive rare earth mining and lack of effective recovery of rare earth，the ad‑ vantages of microbial technology in leaching rare earth from low-grade tailings and recovering rare earth from waste are focused，and the research on microbial leaching of rare earth and related mechanisms are emphatical‑ ly introduced，mainly including microbial leaching，recovery，enrichment and purification of rare earth. The main defects of microbial leaching of rare earth are briefly described. The research direction and challenges of microbial leaching technology in rare earth field are prospected based on the existing research achievements. © 2024 Editorial Office of Chinese Rare Earths. All rights reserved.

引用

页码：468 / 481

页数：13

共 108 条

[1] Recycling and substitu‑ tion of light rare earth elements，cerium，lanthanum，neodymium，and praseodymium from end-of-life applica‑ tions-A review ［J］, J. Cleaner Prod, 236, (2019)
[2] ［2］Syrvatka V，Rabets A，Gromyko O，Luzhetskyy A，Fe‑ dorenko V. Scandium-microorganism interactions in new biotechnologies［J］, Trends Biotechnol, 40, 9, (2022)
[3] Bian X，, Liu Z N，, Gu M Y，, Wu W Y，, Li B K., Extraction of rare earths from bastnaesite concentrates：A critical review and perspective for the future ［J］, Miner. Eng, 171, (2021)
[4] Tong S L，, Zhu W Z，, Gao Z H，, Meng Y X，, Peng R L，, Lu G C., Distribution characteristics of rare earth ele‑ ments in children´s scalp hair from a rare earths mining area in southern China ［J］, Environ. Lett, 39, 9, (2004)
[5] Environmental impacts of rare earth production［J］, MRS Bull, 47, 3, (2022)
[6] Abaka-Wood G B，, Ehrig K，, Addai-Mensah J，, Skinner W., Recovery of rare earth elements minerals from iron-oxide-silicate-rich tailings：Research review ［J］, Eng, 3, 2, (2022)
[7] Ou X L，, Chen Z B，, Chen X L，, Li X F，, Wang J，, Ren T J，, Chen H B，, Feng L J，, Wang Y K，, Chen Z Q, Gao P C., Redistribution and chemical specia‑ tion of rare earth elements in an ion-adsorption rare earth tailing，Southern China［J］, Sci. Total Environ, 821, (2022)
[8] Strategies and options for the sustainable recovery of rare earth elements from electrical and elec‑ tronic waste［J］, Chem. Eng. J, 442, (2022)
[9] Dushyantha N P，, Mancheri N，, Ed- irisinghe P M，, Neethling S J，, Ratnayake N P，, Rohitha L P S，, Dissanayake D M D O K，, Premasiri H M R，, Abeysinghe A M K B，, Dharmaratne P G R，, Batapola N M., Constraints to rare earth elements supply diversifi‑ cation：Evidence from an industry survey［J］, J. Clean‑ er Prod, 331, (2022)
[10] Ruberti M., Rare earth elements as critical raw materials：Focus on international markets and fu‑ ture strategies［J］, Resources Policy, 38, 1, (2013)

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