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Chem Geol, 2005, 219（1-4）: 53 Moriwaki H, Koide R, Yoshikawa R, et al. Adsorption of rare earth ions onto the cell walls of wild-type and lipoteichoic acid￾defective strains of Bacillus subtilis. Appl Microbiol Biotechnol, 2012, 97（8）: 3721 [45] Maleke M, Valverde A, Vermeulen J G, et al. Biomineralization and bioaccumulation of europium by a thermophilic metal resistant bacterium. Front Microbiol, 2019, 10: 81 [46] Hassanoen W A G, Desouky O A N, Hussien S S E. Bioleaching of some rare earth elements from Egyptian monazite using Aspergillus ficuum and Pseudomonas aeruginosa. Walailak J Sci Technol, 2014, 11（9）: 809 [47] Corbett M K, Eksteen J J, Niu X Z, et al. Interactions of phosphate solubilising microorganisms with natural rare-earth phosphate minerals: a study utilizing Western Australian monazite. Bioprocess Biosyst Eng, 2017, 40（6）: 929 [48] Desouky O A, El-Mougith A A, Hassanien W A, et al. Extraction of some strategic elements from thorium–uranium concentrate us￾ing bioproducts of Aspergillus ficuum and Pseudomonas aeruginosa. Arabian J Chem, 2016, 9（Suppl 1）: S795 [49] Feng M H, Ngwenya B T, Wang L, et al. Bacterial dissolution of fluorapatite as a possible source of elevated dissolved phosphate in the environment. Geochim Cosmochim Acta, 2011, 75（19）: 5785 [50] Kim Y, Bae B, Choung Y K. Optimization of biological phosphorus removal from contaminated sediments with phosphate￾solubilizing microorganisms. J Biosci Bioeng, 2005, 99（1）: 23 [51] Zhang L M, Dong H L, Liu Y, et al. Bioleaching of rare earth elements from bastnaesite-bearing rock by actinobacteria. Chem Geol, 2018, 483: 544 [52] Liang C L, Duan M J, Chen L K, et al. Biosorption of yttrium base heavy rare earth ions by Serratia marcescens. J Chin Soc Rare Earths, 2018, 36（3）: 328 （梁长利, 段敏静, 陈陵康, 等. 粘质沙雷氏菌对重钇稀土离子的 生物吸附. 中国稀土学报, 2018, 36（3）：328 ） [53] Qu Y, Lian B. Bioleaching of rare earth and radioactive elements from red mud using Penicillium tricolor RM-10. Bioresour Technol, 2013, 136: 16 [54] Tsuruta T. Selective accumulation of light or heavy rare earth elements using gram-positive bacteria. Colloids Surf B, 2006, 52（2）: 117 [55] Binnemans K, Jones P T, Blanpain B, et al. Towards zero-waste valorisation of rare-earth-containing industrial process residues: a critical review. J Cleaner Prod, 2015, 99: 17 [56] Andrès Y, Thouand G, Boualam M, et al. Factors influencing the biosorption of gadolinium by micro-organisms and its mobilisation from sand. Appl Microbiol Biotechnol, 2000, 54（2）: 262 [57] Kazy S K, Das S K, Sar P. Lanthanum biosorption by a Pseudomonas sp.: equilibrium studies and chemical characterization. J Ind Microbiol Biotechnol, 2006, 33（9）: 773 [58] Xu S X, Zhang S M, Chen K, et al. Biosorption of La3+ and Ce3+ [59] by Agrobacterium sp. HN1. J Rare Earths, 2011, 29（3）: 265 Palmieri M C, Garcia Jr O, Melnikov P. Neodymium biosorption from acidic solutions in batch system. Process Biochem, 2000, 36（5）: 441 [60] Vlachou A, Symeopoulos B D, Koutinas A A. A comparative study of neodymium sorption by yeast cells. Radiochim Acta, 2009, 97（8）: 437 [61] Hosomomi Y, Baba Y, Kubota F, et al. Biosorption of rare earth elements by Escherichia coli. J Chem Eng Jpn, 2013, 46（7）: 450 [62] Wang H Q. Studies on Adsorption of the Rare Earth Ions by Phanerochaete Chrysosporium[Dissertation]. Zhengzhou: Henan Agricultural University, 2008 （王慧琴. 黄孢原毛平革菌对稀土离子的吸附作用研究[学位论 文]. 郑州: 河南农业大学, 2008） [63] Wen J K, Yao G C, Chen B W, et al. Effect of temperature on the activity of mineral-bioleaching microorganisms and the bioleaching rate of copper. J Univ Sci Technol Beijing, 2009, 31（3）: 295 （温建康, 姚国成, 陈勃伟, 等. 温度对浸矿微生物活性及铜浸出 率的影响. 北京科技大学学报, 2009, 31（3）：295 ） [64] Fathollahzadeh H, Hackett M J, Khaleque H N, et al. Better together: Potential of co-culture microorganisms to enhance bioleaching of rare earth elements from monazite. Bioresour Technol Rep, 2018, 3: 109 [65] Brandl H, Faramarzi M A. Microbe-metal-interactions for the biotechnological treatment of metal-containing solid waste. China Particuology, 2006, 4（2）: 93 [66] Liu Y, Hou Z Q. A synthesis of mineralization styles with an integrated genetic model of carbonatite-syenite-hosted REE deposits in the Cenozoic Mianning-Dechang REE metallogenic belt, the eastern Tibetan Plateau, southwestern China. J Asian Earth Sci, 2017, 137: 35 [67] Shin D, Kim J, Kim B S, et al. Use of phosphate solubilizing bacteria to leach rare earth elements from monazite-bearing ore. Minerals, 2015, 5（2）: 189 [68] Binnemans K, Jones P T, Blanpain B, et al. Recycling of rare earths: a critical review. J Cleaner Prod, 2013, 51: 1 [69] Tkaczyk A H, Bartl A, Amato A, et al. Sustainability evaluation of essential critical raw materials: cobalt, niobium, tungsten and rare earth elements. J Phys D Appl Phys, 2018, 51（20）: 203001 [70] Hopfe S, Flemming K, Lehmann F, et al. Leaching of rare earth elements from fluorescent powder using the tea fungus Kombucha. Waste Manage, 2017, 62: 211 [71] Marra A, Cesaro A, Rene E R, et al. Bioleaching of metals from WEEE shredding dust. J Environ Manage, 2018, 210: 180 [72] Reed D W, Fujita Y, Daubaras D L, et al. Bioleaching of rare earth elements from waste phosphors and cracking catalysts. Hydrometallurgy, 2016, 166: 34 [73] Klauber C, Grafe M, Power G. Bauxite residue issues: II. options for residue utilization. Hydrometallurgy, 2011, 108（1-2）: 11 [74] [75] Yin S H, Wang L M, Wu A X, et al. Progress of research in copper · 68 · 工程科学学报，第 42 卷，第 1 期