刘晓璐等:微生物技术在稀土资源利用中的研究进展 67 7(6:207 113(2):339 [16]Ji G Y,Zhang H P,Li Q L,et al.Current status of rare earth [30]Goyne K W,Brantley S L,Chorover J.Rare earth element release resources in China and strategies for its sustainable development. from phosphate minerals in the presence of organic acids.Chem China Min Mag,2018,27(8):9 Geol,2010,278(1-2):1 (季根源,张洪平,李秋玲,等.中国稀土矿产资源现状及其可持 [31]Sashidhar B,Podile A R.Mineral phosphate solubilization by 续发展对策.中国矿业,2018,27(8):9) rhizosphere bacteria and scope for manipulation of the direct [17]Abreu RD,Morais CA.Purification of rare earth elements from oxidation pathway involving glucose dehydrogenase.J App/ monazite sulphuric acid leach liquor and the production of high- Microbiol,.2010,109(1):1 purity ceric oxide.Miner Eng,2010,23(6):536 [32]Reyes I,Bemier L,Simard RR,et al.Effect of nitrogen source on [18]Liu Q.Zhou F,Feng J,et al.Review on rare earth resoueces and the solubilization of different inorganic phosphates by an isolate of its mineral processing technology in China.Conservation Penicillium rugulosum and two UV-induced mutants.FEMS Utilization Miner Resour,2019,39(5):76 Microbiol Ecol,1999,28(3):281 (刘琦,周芳,冯健,等.我国稀土资源现状及选矿技术进展.矿 [33]Corbett M K,Eksteen J J,Niu X Z,et al.Syntrophic effect of 产保护与利用,2019,39(5):76) indigenous and inoculated microorganisms in the leaching of rare [19]Ober J A.Mineral commodity summaries 2017[R/OL].U.S. earth elements from Western Australian monazite.Res Microbiol. Geological Survey (2017-1-31)[2019-9-121. 2018.169(10):558 https://pubs.er.usgs.gov/publication/70180197 [34]Sand W,Gehrke T.Extracellular polymeric substances mediate [20]Yuan Z X,Bai G.Temporal and spatial distribution of endogenic bioleaching/biocorrosion via interfacial processes involving iron rare and rare earth mineral deposits of China.Miner Deposits, (III)ions and acidophilic bacteria.Res Microbiol,2006,157(1): 2001,20(4):347 49 (袁忠信,白鸽.中国内生稀有稀土矿床的时空分布.矿床地质, [35]Fathollahzadeh H,Becker T,Eksteen JJ,et al.Microbial contact 2001,20(4):347) enhances bioleaching of rare earth elements.Bioresour Technol [21]Liu J,Ling M X,Li Y,et al.REE ore-forming models of giant Rep,2018,3:102 Bayan Obo REE-Nb-Fe ore deposit:a review.Geofeconica et [36]Oliveira R C,Jouannin C,Guibal E,et al.Samarium (III)and Metallogenia,2009,33(2):270 praseodymium (III)biosorption on Sargassum sp.:batch study. (刘健,凌明星,李印,等.白云鄂博超大型REE-Nb-Fε矿床的稀 Process Biochem,2011,46(3):736 土成模式综述.大地构造与成矿学,2009,33(2):270) [37]Das N,Das D.Recovery of rare earth metals through biosorption [22]Brandl H,Barmettler F,Castelberg C,et al.Microbial mobilization an overview.J Rare Earths,2013,31(10):933 of rare earth elements (REE)from mineral solids-a mini review [38]Liu A M.Isolation and the Mechanism of Cd*Adsorption of A AIMS Microbiol,2016,3(2):190 Cadmiu-tolerant Bacterium and Its Application in Restoring [23]Mullen M D,Wolf D C,Ferris F G,et al.Bacterial sorption of Cadmium-contaminated Soils[Dissertation].Nanjing:Nanjing heavy metals.Appl Environ Microbiol,1989,55(12):3143 Agricultural University,2005 [24]Ozaki T,Suzuki Y,Nankawa T,et al.Interactions of rare earth (刘爱民.耐镉细菌筛选与吸附镉机理研究及其在镉污染土壤 elements with bacteria and organic ligands.JAlloys Compd,2006, 修复中的应用[学位论文].南京:南京农业大学,2005) 408-412:1334 [39]Goyal N,Jain S C,Banerjee U C.Comparative studies on the [25]Horiike T,Yamashita M.A new fungal isolate,Penidiella sp. microbial adsorption of heavy metals.Ady Environ Res,2003, strain T9,accumulates the rare earth element dysprosium.Appl 7(2):311 Environ Microbiol,2015,81(9):3062 [40]Philip L,Iyengar L,Venkobachar C.Biosorption of U,La,Pr,Nd, [26]Bonificio W D,Clarke D R.Rare-earth separation using bacteria. Eu and Dy by Pseudomonas aeruginosa.J Ind Microbiol Environ Sci Technol Lett,2016,3(4):180 Biotechnol,2000,25(1):1 [27]Moriwaki H,Yamamoto H.Interactions of microorganisms with [41]Gadd G M.Metals,minerals and microbes:geomicrobiology and rare earth ions and their utilization for separation and bioremediation.Microbiology,2009,156(3):609 environmental technology.Appl Microbiol Biotechnol,2012, [42]Tsuruta T.Accumulation of rare earth elements in various 97(1):1 microorganisms.J Rare Earths,2007,25(5):526 [28]Meng C Y,Jing Q K,Ma J,et al.Overview of microbiological [43]Shi X L.Studies on Adsorption of the Rare Earth by Aspergillus technology for recovery of rare metal resources.Chin J Rare Met, Niger[Dissertation].Zhengzhou:Henan Agricultural University, 2015,39(4):371 2008 (孟春瑜,荆乾坤,马骏,等,微生物技术在稀有金属资源利用中 (史小利.黑曲霉对稀土离子的生物吸附研究学位论文]郑州: 的研究概况.稀有金属,2015,39(4):371) 河南农业大学,2008) [29]Brisson V L,Zhuang W Q,Alvarez-Cohen L.Bioleaching of rare [44]Takahashi Y,Chatellier X,Hattori K H,et al.Adsorption of rare earth elements from monazite sand.Biotechnol Bioeng,2016, earth elements onto bacterial cell walls and its implication for REE7(6): 207 Ji G Y, Zhang H P, Li Q L, et al. Current status of rare earth resources in China and strategies for its sustainable development. China Min Mag, 2018, 27(8): 9 (季根源, 张洪平, 李秋玲, 等. 中国稀土矿产资源现状及其可持 续发展对策. 中国矿业, 2018, 27(8):9 ) [16] Abreu R D, Morais C A. Purification of rare earth elements from monazite sulphuric acid leach liquor and the production of highpurity ceric oxide. Miner Eng, 2010, 23(6): 536 [17] Liu Q, Zhou F, Feng J, et al. Review on rare earth resoueces and its mineral processing technology in China. Conservation Utilization Miner Resour, 2019, 39(5): 76 (刘琦, 周芳, 冯健, 等. 我国稀土资源现状及选矿技术进展. 矿 产保护与利用, 2019, 39(5):76 ) [18] Ober J A. Mineral commodity summaries 2017[R/OL]. U.S. Geological Survey (2017-1-31)[2019-9-12]. https://pubs.er.usgs.gov/publication/70180197 [19] Yuan Z X, Bai G. Temporal and spatial distribution of endogenic rare and rare earth mineral deposits of China. Miner Deposits, 2001, 20(4): 347 (袁忠信, 白鸽. 中国内生稀有稀土矿床的时空分布. 矿床地质, 2001, 20(4):347 ) [20] Liu J, Ling M X, Li Y, et al. REE ore-forming models of giant Bayan Obo REE ‒Nb ‒Fe ore deposit: a review. Geoteconica et Metallogenia, 2009, 33(2): 270 (刘健, 凌明星, 李印, 等. 白云鄂博超大型REE‒Nb−Fe矿床的稀 土成矿模式综述. 大地构造与成矿学, 2009, 33(2):270 ) [21] Brandl H, Barmettler F, Castelberg C, et al. Microbial mobilization of rare earth elements (REE) from mineral solids—a mini review. AIMS Microbiol, 2016, 3(2): 190 [22] Mullen M D, Wolf D C, Ferris F G, et al. Bacterial sorption of heavy metals. Appl Environ Microbiol, 1989, 55(12): 3143 [23] Ozaki T, Suzuki Y, Nankawa T, et al. Interactions of rare earth elements with bacteria and organic ligands. J Alloys Compd, 2006, 408-412: 1334 [24] Horiike T, Yamashita M. A new fungal isolate, Penidiella sp. strain T9, accumulates the rare earth element dysprosium. Appl Environ Microbiol, 2015, 81(9): 3062 [25] Bonificio W D, Clarke D R. Rare-earth separation using bacteria. Environ Sci Technol Lett, 2016, 3(4): 180 [26] Moriwaki H, Yamamoto H. Interactions of microorganisms with rare earth ions and their utilization for separation and environmental technology. Appl Microbiol Biotechnol, 2012, 97(1): 1 [27] Meng C Y, Jing Q K, Ma J, et al. Overview of microbiological technology for recovery of rare metal resources. Chin J Rare Met, 2015, 39(4): 371 (孟春瑜, 荆乾坤, 马骏, 等. 微生物技术在稀有金属资源利用中 的研究概况. 稀有金属, 2015, 39(4):371 ) [28] Brisson V L, Zhuang W Q, Alvarez-Cohen L. Bioleaching of rare earth elements from monazite sand. Biotechnol Bioeng, 2016, [29] 113(2): 339 Goyne K W, Brantley S L, Chorover J. Rare earth element release from phosphate minerals in the presence of organic acids. Chem Geol, 2010, 278(1-2): 1 [30] Sashidhar B, Podile A R. Mineral phosphate solubilization by rhizosphere bacteria and scope for manipulation of the direct oxidation pathway involving glucose dehydrogenase. J Appl Microbiol, 2010, 109(1): 1 [31] Reyes I, Bernier L, Simard R R, et al. Effect of nitrogen source on the solubilization of different inorganic phosphates by an isolate of Penicillium rugulosum and two UV-induced mutants. FEMS Microbiol Ecol, 1999, 28(3): 281 [32] Corbett M K, Eksteen J J, Niu X Z, et al. Syntrophic effect of indigenous and inoculated microorganisms in the leaching of rare earth elements from Western Australian monazite. Res Microbiol, 2018, 169(10): 558 [33] Sand W, Gehrke T. Extracellular polymeric substances mediate bioleaching/biocorrosion via interfacial processes involving iron (III) ions and acidophilic bacteria. Res Microbiol, 2006, 157(1): 49 [34] Fathollahzadeh H, Becker T, Eksteen J J, et al. Microbial contact enhances bioleaching of rare earth elements. Bioresour Technol Rep, 2018, 3: 102 [35] Oliveira R C, Jouannin C, Guibal E, et al. Samarium (III) and praseodymium (III) biosorption on Sargassum sp.: batch study. Process Biochem, 2011, 46(3): 736 [36] Das N, Das D. Recovery of rare earth metals through biosorption: an overview. J Rare Earths, 2013, 31(10): 933 [37] Liu A M. Isolation and the Mechanism of Cd2+ Adsorption of A Cadmiu-tolerant Bacterium and Its Application in Restoring Cadmium-contaminated Soils[Dissertation]. Nanjing: Nanjing Agricultural University, 2005 (刘爱民. 耐镉细菌筛选与吸附镉机理研究及其在镉污染土壤 修复中的应用[学位论文]. 南京: 南京农业大学, 2005) [38] Goyal N, Jain S C, Banerjee U C. Comparative studies on the microbial adsorption of heavy metals. Adv Environ Res, 2003, 7(2): 311 [39] Philip L, Iyengar L, Venkobachar C. Biosorption of U, La, Pr, Nd, Eu and Dy by Pseudomonas aeruginosa. J Ind Microbiol Biotechnol, 2000, 25(1): 1 [40] Gadd G M. Metals, minerals and microbes: geomicrobiology and bioremediation. Microbiology, 2009, 156(3): 609 [41] Tsuruta T. Accumulation of rare earth elements in various microorganisms. J Rare Earths, 2007, 25(5): 526 [42] Shi X L. Studies on Adsorption of the Rare Earth by Aspergillus Niger[Dissertation]. Zhengzhou: Henan Agricultural University, 2008 (史小利. 黑曲霉对稀土离子的生物吸附研究[学位论文]. 郑州: 河南农业大学, 2008) [43] Takahashi Y, Chatellier X, Hattori K H, et al. Adsorption of rare earth elements onto bacterial cell walls and its implication for REE [44] 刘晓璐等: 微生物技术在稀土资源利用中的研究进展 · 67 ·