Surface nanobubble characterization and its enhancement mechanisms for fine-particle flotation:A review 被引量：8

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摘要 Froth flotation is often used for fine-particle separation,but its process efficiency rapidly decreases with decreasing particle size.The efficient separation of ultrafine particles(UFPs)has been a major challenge in the mineral processing field for many years.In recent years,the use of surface nanobubbles in the flotation process has been recognized as an effective approach for enhancing the recovery of UFPs.Compared with traditional macrobubbles,nanobubbles possess unique surface and bulk characteristics,and their effects on the UFP flotation behavior have been a topic of intensive research.This review article is focused on the studies on various unique characteristics of nanobubbles and their mechanisms of enhancing the UFP flotation.The purpose of this article is to summarize the major achievements on the two topics and pinpoint future research needs for a better understanding of the fundamentals of surface nanobubble flotation and developing more feasible and efficient processes for fine and UFPs.

作者 Fangyuan Ma Patrick Zhang Dongping Tao

机构地区 School of Resources and Environmental Engineering Florida Industrial and Phosphate Research Institute

出处《International Journal of Minerals,Metallurgy and Materials》 SCIE EI CAS CSCD 2022年第4期727-738,共12页 矿物冶金与材料学报（英文版）

基金 funded by a number of government and industrial grants,particularly the grant from the National Natural Science Foundation of China(No.51804188)。

关键词 surface nanobubbles CHARACTERIZATION FLOTATION ultrafine particles high-efficiency separation

分类号 TD923 [矿业工程—选矿]

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参考文献7

1Qian-yu Sun,Wan-zhong Yin,Dong Li,Ya-feng Fu,Ji-wei Xue,Jin Yao.Improving the sulfidation-flotation of fine cuprite by hydrophobic flocculation pretreatment[J].International Journal of Minerals,Metallurgy and Materials,2018,25(11):1256-1262. 被引量：9
2Fangyuan Ma,Dongping Tao,Youjun Tao,Shuyong Liu.An innovative flake graphite upgrading process based on HPGR,stirred grinding mill, and nanobubble column flotation[J].International Journal of Mining Science and Technology,2021,31(6):1063-1074. 被引量：17
3Ahmadi Rahman,Khodadadi Darban Ahmad,Abdollahy Mahmoud,Fan Maoming.Nano-microbubble flotation of fine and ultrafine chalcopyrite particles[J].International Journal of Mining Science and Technology,2014,24(4):559-566. 被引量：32
4Xu-yu Zhang,Qian-shuai Wang,Zhong-xian Wu,Dong-ping Tao.An experimental study on size distribution and zeta potential of bulk cavitation nanobubbles[J].International Journal of Minerals,Metallurgy and Materials,2020,27(2):152-161. 被引量：19
5FAN Maoming,TAO Daniel,HONAKER Rick,LUO Zhenfu.Nanobubble generation and its application in froth flotation (part I): nanobubble generation and its effects on properties of microbubble and millimeter scale bubble solutions[J].Mining Science and Technology,2010,20(1):1-19. 被引量：36
6张立娟,方海平,胡钧.纳米气泡的科学之谜[J].物理,2018,47(9):574-583. 被引量：12
7Sabereh Nazari,Sied Ziaedin Shafaei,Mahdi Gharabaghi,Rahman Ahmadi,Behzad Shahbazi,Fan Maoming.Effects of nanobubble and hydrodynamic parameters on coarse quartz flotation[J].International Journal of Mining Science and Technology,2019,29(2):289-295. 被引量：19

二级参考文献49

1TAO Daniel,HONAKER Rick.Nanobubble generation and its applications in froth flotation(part Ⅱ):fundamental study and theoretical analysis[J].Mining Science and Technology,2010,20(2):159-177. 被引量：29
2B.Shahbazi,B.Rezai,S.Chehreh Chelgani,S.M.Javad Koleini,M.Noaparast.Estimation of diameter and surface area flux of bubbles based on operational gas dispersion parameters by using regression and ANFIS[J].International Journal of Mining Science and Technology,2013,23(3):343-348. 被引量：4
3Wu Z H,Chen H B,Dong Y M,Mao H L,Sun J L,Chen S F,Vincent S J C,Hu J.Cleaning using nanobubbles:defouling by electrochemical generation of bubbles.Journal of Colloid and Interface Science,2008,328(1):10-14.
4Wang Y,Li X,Zhou Y,Huang P Y,Xu Y H.Preparation of nanobubbles for ultrasound imaging and intracelluar drug delivery.International Journal of Pharmaceutics,2001,384(1-2):148-153.
5Suzuki M,Koshiyama K,Shinohara F,Mori S,Ono M,Tomita Y,Yano T,Fujikawa S,Vassaux G,Kodama T.Nanobubbles enhanced drug susceptibility of cancer cells using ultrasound.International Congress Series,2005(1284):338-339.
6Zhou Z A,Xu Z H,Finch J A,Masliyah J H,Chow R S.On the role of cavitation in particle collection in flotation:a critical review Ⅱ.Minerals Engineering,2009,22(5):419-433.
7Yoon R H,Luttrell G H.The effect of bubble size on fine particle flotation.Mineral Processing & Extractive Metallurgical Review,1989(5):101-122.
8Yalamanchili M R,Miller J D.Removal of insoluble slimes from potash ore by air-sparged hydrocyclone flotation.Minerals Engineering,1995,8(1-2):169-177.
9Tao D.Role of bubble size in flotation of coarse and fine particles-a review.Separation Science and Technology,2004,39(4):741-760.
10Xu M,Quinn P,Stratton-Crawly R A.A feed-line aerated flotation column.Minerals Engineering,1996,9(5):499-508.

共引文献112

1张凡凡,曹亦俊,邢耀文,桂夏辉,孙丽娟,杨海昌,李明.微纳尺度下浮选颗粒气泡间相互作用行为试验研究[J].煤炭学报,2022,47(S01):276-284. 被引量：2
2李臣威,张海军.纳米气泡对锂电池电极材料浮选行为的影响[J].煤炭学报,2022,47(S01):257-264. 被引量：2
3郭幸斐,晁淑琳,黄亚琪.纳米气泡对有机溶液表观黏度的影响研究[J].化学工业与工程,2023,40(6):144-150. 被引量：1
4TAO Daniel,HONAKER Rick.Nanobubble generation and its applications in froth flotation(part Ⅱ):fundamental study and theoretical analysis[J].Mining Science and Technology,2010,20(2):159-177. 被引量：29
5FAN Maoming,TAO Daniel,HONAKER Rick,LUO Zhenfu.Nanobubble generation and its applications in froth flotation(partⅢ):specially designed laboratory scale column flotation of phosphate[J].Mining Science and Technology,2010,20(3):317-338. 被引量：19
6XIE Guangyuan,WU Ling,LI Guozhou,YU Hesheng.Coal flotation using wash oil as a new type of collector[J].Mining Science and Technology,2010,20(4):546-550.
7FAN Maoming,TAO Danie,HONAKER Rick,LUO Zhenfu.Nanobubble generation and its applications in froth flotation(part IV):mechanical cells and specially designed column flotation of coal[J].Mining Science and Technology,2010,20(5):641-671. 被引量：18
8骆振福,郭进,赵跃民,陈增强,梁春成.表面改性加重质的流态化及其分选性能[J].中国矿业大学学报,2011,40(1):111-115. 被引量：3
9Shirleny Fontes Santos,Silvia Cristina Alves Franca,Tsuneharu Ogasawara.Method for grinding and delaminating muscovite[J].Mining Science and Technology,2011,21(1):7-10. 被引量：1
10Li Haibin Luo Zhenfu Zhao Yuemin Wu Wanchang Zhang Cuiyu Dai Ningning.Cleaning of South African coal using a compound dry cleaning apparatus[J].Mining Science and Technology,2011,21(1):117-121. 被引量：3

同被引文献77

1TAO Daniel,HONAKER Rick.Nanobubble generation and its applications in froth flotation(part Ⅱ):fundamental study and theoretical analysis[J].Mining Science and Technology,2010,20(2):159-177. 被引量：29
2肖庆苏,李长根,康桂英.柿竹园多金属矿CF法浮选钨主干全浮选矿工艺研究[J].矿冶,1996,5(3):26-32. 被引量：31
3叶清,夏福军,朱南文.诱导射流气浮选和微动力过滤器处理含油污水[J].工业水处理,2008,28(3):45-47. 被引量：2
4郭敏,李权,刘海宁,叶秀深,卿彬菊,葛飞,吴志坚.盐湖镁资源的开发和利用[J].化学进展,2009,21(11):2358-2364. 被引量：22
5陶有俊,刘谦,Daniel TAO,陶秀祥.纳米泡提高细粒煤浮选效果的研究[J].中国矿业大学学报,2009,38(6):820-823. 被引量：24
6印万忠,张丽荣,谢峰.Flotation of Xinhua molybdenite using sodium sulfide as modifier[J].Transactions of Nonferrous Metals Society of China,2010,20(4):702-706. 被引量：7
7FAN Maoming,TAO Daniel,HONAKER Rick,LUO Zhenfu.Nanobubble generation and its applications in froth flotation(partⅢ):specially designed laboratory scale column flotation of phosphate[J].Mining Science and Technology,2010,20(3):317-338. 被引量：19
8陈建华,冯其明,卢毅屏.新型铜铅分离有机抑制剂ASC的研究[J].矿产保护与利用,2000,20(5):39-42. 被引量：35
9张忠汉,张先华,叶志平,戴子林,童金堂,过建光.柿竹园多金属矿GY法浮钨新工艺研究[J].矿冶工程,1999,19(4):22-25. 被引量：53
10Bijan Taheri,Mahmoud Abdollahy,Sied Ziaedin Shafaei Tonkaboni,Soheyla Javadian,Mohammadreza Yarahmadi.Dual effects of sodium sulfide on the flotation behavior of chalcopyrite:Ⅰ. Effect of pulp potential[J].International Journal of Minerals,Metallurgy and Materials,2014,21(5):415-422. 被引量：4

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2卢肖,马芳源.体相纳米气泡的制备方法及强化细颗粒矿物浮选机理研究现状[J].中国矿业,2023,32(10):111-117. 被引量：1
3Xiufeng Gong,Jin Yao,Jun Guo,Bin Yang,Haoran Sun,Wanzhong Yin,Yulian Wang,Yafeng Fu.Role of tannin pretreatment in flotation separation of magnesite and dolomite[J].International Journal of Minerals,Metallurgy and Materials,2024,31(3):452-461. 被引量：2
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6Shuming Wen.Thermodynamic theory of flotation for a complex multiphase solid -liquid system and high-entropy flotation[J].International Journal of Minerals,Metallurgy and Materials,2024,31(6):1177-1197.
7赵奕锦,王嫣格,芮俊男,邱宇平.水体微塑料的浮选分离:原理、效果、机制与调控[J].中国环境科学,2024,44(9):5234-5247.
8吴中贤,周波,董鸿良,冉金城,陶东平.纳米气泡对金矿浮选效果影响的探索[J].黄金,2025,46(1):89-94.

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3马芳源,崔守慧,张羽翔.细颗粒煤炭纳米气泡高效浮选及其机理研究[J].矿业研究与开发,2024,44(11):247-252.
4Xiufeng Gong,Jin Yao,Wanzhong Yin,Jianwei Yu,Bin Yang,Yulian Wang.Investigation of the flotation behavior and interaction characteristics of micro-fine quartz and magnesite in a dodecylamine system under ultrasonic treatment[J].Particuology,2024,94(11):386-399. 被引量：1
5Fen Jiao,Zheyi Zhang,Qian Wei,Wenqing Qin.Key technologies and development trends for efficient flotation recovery of lepidolite[J].Green and Smart Mining Engineering,2024,1(3):273-288.
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1Andrea L.Moreno-Ríos,Lesly P.Tejeda-Benítez,Ciro F.Bustillo-Lecompte.Sources,characteristics,toxicity,and control of ultrafine particles:An overview[J].Geoscience Frontiers,2022,13(1):512-526. 被引量：2
2Fangyuan Ma,Dongping Tao,Youjun Tao,Shuyong Liu.An innovative flake graphite upgrading process based on HPGR,stirred grinding mill, and nanobubble column flotation[J].International Journal of Mining Science and Technology,2021,31(6):1063-1074. 被引量：17
3Bing Yan,Bo Chen,Yongliang Xiong,Zerui Peng.Effect of Joule heating on the electroosmotic microvortex and dielectrophoretic particle separation controlled by local electric field[J].Chinese Physics B,2021,30(11):401-410.
4Marcel Zillgitt,Eberhard Schmidt.Quantification of particle separation using electrostatically charged spray mist in a dust chamber[J].Particuology,2021,19(5):92-98.
5Liping Luo,Longhua Xu,Xinzhang Shi,Jinping Meng,Ruohua Liu.Microscale insights into the influence of grinding media on spodumene micro-flotation using mixed anionic/cationic collectors[J].International Journal of Mining Science and Technology,2022,32(1):171-179. 被引量：9
6Underlining the Fundamentals[J].Beijing Review,2022,65(9):2-2.
7Richard Danzig.Countering COVID-19 in 2021 and Beyond:More Cooperation is Required Between the Governments of China and the USA[J].China CDC weekly,2021,3(7):138-139.
8王丰婷.文本类型理论指导下科技英语翻译研究——以自然杂志Facial-recognition Research Needs an Ethical Reckoning文本为例[J].英语广场（学术研究）,2021(36):10-13.
9Zhiwen Li,Jiangli.Prevention and Control of Birth Defects in China:Achievements and Challenges[J].China CDC weekly,2021,3(37):771-772. 被引量：3
10Ana Teresa Juarez-Facio,Clement Castilla,Cecile Corbiere,Helene Lavanant,Carlos Afonso,Christophe Morin,Nadine Merlet-Machour,Laurence Chevalier,Jean-Marie Vaugeois,Jerome Yon,Christelle Monteil.Development of a standardized in vitro approach to evaluate microphysical,chemical,and toxicological properties of combustion-derived fine and ultrafine particles[J].Journal of Environmental Sciences,2022,34(3):104-117.

International Journal of Minerals,Metallurgy and Materials

2022年第4期

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