黄金杂志社

登录账号

Ｘ

中国科技核心期刊

美国化学文摘社（CAS）数据库

美国EBSCO学术数据库

日本科学技术振兴机构数据库(JST)

作者投稿专家审稿编辑办公

期刊导读

2025年

2024年

2023年

2022年

2021年

2020年

2019年

首页 > 矿业工程

纳米气泡的发展历程及其稳定性研究进展

李明娇|高国峰|王吉|王承文|马芳源|孙孝东|王睿
作者单位：
辽宁科技大学矿业工程学院|鞍钢集团朝阳钢铁有限公司|鞍钢集团朝阳钢铁有限公司|鞍钢矿业爆破有限公司|辽宁科技大学矿业工程学院|鞍山钢铁集团有限公司大孤山球团厂|辽宁科技大学矿业工程学院
基金项目：
辽宁省教育厅高等学校基本科研项目(LJKQZ20222340)；辽宁科技大学博士启动基金；辽宁科技大学大学生创新创业训练计划项目
详细信息：
作者简介：
李明娇（2004—），女，研究方向为细颗粒矿物浮选；E-mail：3068244273@qq.com
通讯作者：
马芳源（1991—），男，讲师，博士，研究方向为细颗粒矿物浮选；E-mail：1209468883@qq.com
PDF下载

Development history of nanobubbles and the research progress on their stability

English Author：
School of Mining Engineering,University of Science and Technology Liaoning|Chaoyang Steel Co.,Ltd.,Ansteel Group Corporation Limited|Chaoyang Steel Co.,Ltd.,Ansteel Group Corporation Limited|Ansteel Mining Blasting Company|School of Mining Engineering,University of Science and Technology Liaoning|Dagushan Pellet Plant,Ansteel Group Corporation Limited|School of Mining Engineering,University of Science and Technology Liaoning
Unit：

摘要
在线预览
参考文献

摘要:

近年来，纳米气泡一直是学术界的研究焦点。纳米气泡性质不同于宏观气泡，被广泛应用于医疗、养殖、矿物浮选等诸多领域，特别是纳米气泡存活数小时甚至几个月的超强稳定性成为当前备受关注的热点话题。然而，纳米气泡的发展历程目前仍缺乏系统总结。针对这一问题，归纳了纳米气泡的发展历程，阐述了纳米气泡的稳定性研究进展，从而指出了这些理论的适用范围和局限性，总结了纳米气泡稳定性对浮选的影响，以期拓展研究纳米气泡潜在的研究价值，为纳米气泡的稳定性研究提供了新方向。

关键词:

纳米气泡；稳定性；发展历程；浮选；机理

Abstract:

In recent years,nanobubbles have become a focal point of academic research.Unlike macroscopic bubbles,nanobubbles possess unique properties that have led to their widespread application in various fields such as medicine,aquaculture,and mineral flotation.Particularly,the ultra-high stability of nanobubbles,which can persist for hours or even months,has become a hot topic.However,a systematic summary of the development history of nanobubbles is still lacking.Addressing this gap,this paper outlines the development history of nanobubbles and discusses the research progress on their stability.The paper also highlights the applicability and limitations of existing theories and summarizes the impact of nanobubble stability on flotation processes.This study aims to expand the potential research value of nanobubbles and provide new directions for further studies on their stability.

Keywords:

nanobubbles;stability;development history;flotation;mechanism

[1]MAFY,TAODP,TAOYJ,etal.AninnovativeflakegraphiteupgradingprocessbasedonHPGR,stirredgrindingmill,andnanobubblecolumnflotation[J].InternationalJournalofMiningScienceandTechnology,2021,31(6):1063-1074.
[2]MAFY,TAODP,TAOYJ.EffectsofnanobubblesincolumnflotationofChinesesub-bituminouscoal[J].InternationalJournalofCoalPreparationandUtilization,2022,42(4):1126-1142.
[3]HUANGH,YANGX,WUZX,etal.Aninvestigationofnanobubbleenhancedflotationforflyashdecarbonization[J].ColloidsandSurfacesA:PhysicochemicalandEngineeringAspects,2023,679:132563.
[4]XUYK,LILS,LOUS,etal.Effectsofnano-aeratorsonmicrobialcommunitiesandfunctionsinthewater,sediment,andshrimpintestineinlitopenaeusvannameiaquacultureponds[J].Microorganisms,2022,10(7):1302.
[5]王丹丹,程凯,郭冀峰.微纳米气泡强化水处理研究进展[J].应用化工,2023,52(5):1454-1459.
[6]熊永磊,杨小丽,宋海亮.微纳米气泡在水处理中的应用及其发生装置研究[J].环境工程,2016,34(6):23-27.
[7]BISMUTHM,KATZS,MANOT,etal.Lowfrequencynanobubble-enhancedultrasoundmechanotherapyfornoninvasivecancersurgery[J].Nanoscale,2022,14(37):13614-13627.
[8]COOLEYMB,ABENOJAREC,WEGIERAK,etal.Characterizationoftheinteractionofnanobubbleultrasoundcontrastagentswithhumanbloodcomponents[J].BioactiveMaterials,2023,19:642-652.
[9]TAODP.Recentadvancesinfundamentalsandapplicationsofnanobubbleenhancedfrothflotation:Areview[J].MineralsEngineering,2022,183:107554.
[10]孟令轩,赵通林,范兆琳,等.纳米气泡强化超细颗粒浮选机理研究现状及展望[J].矿产保护与利用,2023,43(2):162-168.
[11]FAVVASEP,KYZASGZ,EFTHIMIADOUEK,etal.Bulknanobubbles,generationmethodsandpotentialapplications[J].CurrentOpinionColloidandInterfaceScience,2021,54:101455.
[12]ZHOULM,WANGXY,SHINHJ,etal.Ultrahighdensityofgasmoleculesconfinedinsurfacenanobubblesinambientwater[J].JournaloftheAmericanChemicalSociety,2022,142:5583-5593.
[13]BUXN,MUIDHA.Theeffectofultrasoundonbulkandsurfacenanobubbles:Areviewofthecurrentstatus[J].UltrasonicsSonochemistry,2021,76:105629.
[14]ZHANGXY,WANGQS,WUZX,etal.Anexperimentalstudyonsizedistributionandzetapotentialofbulkcavitationnanobubbles[J].InternationalJournalofMinerals,MetallurgyandMaterials,2021,27(2):152-161.
[15]ISHIDAN,INOUET,MIYAHARAM,etal.Nanobubblesonahydrophobicsurfaceinwaterobservedbytapping-modeatomicforcemicroscopy[J].Langmuir,2000,16(16):6377-6380.
[16]莫鼎成,肖雅龄.关于菲克第二定律解的适用范围讨论[J].化学通报,1990(6):50-51.
[17]ZHANGLJ,FANGHP,HUJ.Sciencemysteriesofnanobubbles[J].Physics,2018,47(9):574-583.
[18]ALHESHIBRIM,QIANJ,JEHANNINM,etal.Ahistoryofnanobubbles[J].Langmuir,2016,32:11086-11100.
[19]EPSTEINPS,PLESSETMS.OnthestabilityofgasBubblesinliquid-gassolutions[J].JournalofChemicalPhysics,1950,18(11):1505-1509.
[20]ISRELACHVILIJ,PASHLEYR.Thehydrophobicinteractionislongrange，decayingexponentiallywithdistance[J].Nature,1982,300(25):341-342.
[21]PARKERJL,CLAESSONPM,ATTARDP.Bubbles,cavities,andthelong-rangedattractionbetweenhydrophobicsurfaces[J].TheJournalofPhysicalChemistry,1994,98(34):8468-8480.
[22]LJUNGGRENS,ERIKSSONJC.Thelifetimeofacolloid-sizedgasbubbleinwaterandthecauseofthehydrophobicattraction[J].ColloidsandSurfacesA:PhysicochemicalandEngineeringAspects,1997(129/130):151-155.
[23]LOUST,OUYANGZQ,ZHANGY,etal.Nanobubblesonsolidsurfaceimagedbyatomicforcemicroscopy[J].JournalofVacuumScience&TechnologyB:MicroelectronicsandNanometerStructures,2000,18(5):2573-2575.
[24]DUBENK,OEFFINGERBE,WHEATLEYMA.Developmentandcharacterizationofanano-sizedsurfactantstabilizedcontrastagentfordiagnosticultrasound[C]∥IEEE.2003IEEE29thAnnualProceedingsofBioengineeringConference.Newark:IEEE,2023.
[25]OHGAKIK,KHANHNQ,JODENY,etal.Physicochemicalapproachtonanobubblesolutions[J].ChemicalEngineeringScience,2010,65(3):1296-1300.
[26]SOBHYA,TAODP.High-efficiencynanobubblecoalflotation[J].InternationalJournalofCoalPreparationandUtilization,2013,33(5):242-256.
[27]SEOD,SEANR,TONYL,etal.Phasestateofinterfacialnanobub-bles[J].JournalofPhysicalChemistryC,2015,119(25):14262-14266.
[28]ZHANGXH,KHANA,DUCKERWA.Ananoscalegasstate[J].PhysicalReviewLetters,2007,98(13):136101.
[29]KARPITSCHKAS,DIETRICHE,SEDDON,etal.Nonintrusiveopticalvisualizationofsurfacenanobubbles[J].PhysicalReviewLetters,2012,109(6):066102.
[30]ZHANGL,ZHAOB,XUEL,etal.Imaginginterfacialmicro-andnano-bubblesbyscanningtransmissionsoftX-raymicroscopy[J].SynchrotronRadiat,2013,20(3):413-418.
[31]BHANDARIP,WANGX,IRUDAYARAJJ.Oxygennanobubbletrackingbylightscatteringinsinglecellsandtissues[J].ACSNano,2017,11:2682-2688.
[32]ETCHEPARER,OLIVERIAH,NICKNIGM,etal.Nanobubbles:Generationusingamultiphasepump,propertiesandfeaturesinflotation[J].MineralsEngineering,2017,112:19-26.
[33]KNUPFERP,DITSCHERLEINL,PEUKERU.Nanobubbleenhancedagglomerationofhydrophobicpowders[J].ColloidsandSurfaceAPhysicochemicaandEngineeringAspects,2017,530:117-123.
[34]TAKATAY,MATSUBARAH,MATSUDAT,etal.Studyonlinetensionofair/hexadecane/aqueoussurfactantsystem[J].ColloidandPolymerScience,2007,286(6/7):647-654.
[35]SCHELUDKOA,CHAKAROVV,TOSHEVB.Watercondensationonhexadecaneandlineartension[J].JournalofColloidandInterfaceScience,1981,82(1):83-92.
[36]TOSHEVBV,PLATIKANOVD,SCHELUDKOA.Linetensioninthree-phaseequilibriumsystems[J].Langmuir,1988,4(3):489-499.
[37]IVANOVIB,KRALCHEVSKYPA,DIMITROVAS,etal.Dynamicsofcontactlinesinfoamfilms[J].AdvancesinColloidandInterfaceScience,1992,39:77-101.
[38]KAMEDAN,NAKABAYASHIS.Size-inducedsigninversionoflinetensioninnanobubblesatasolid/liquidinterface[J].ChemicalPhysicsLetters,2008,461(1/2/3):122-126.
[39]YANGJ,DUANJW,FONASIERODM,etal.Verysmallbubbleformationatthesolid-waterinterface[J].TheJournalofPhysicalChemistryB,2003,107(25):6139-6147.
[40]PENGH,BIRKETTGR,NGUYENAV.Progressonthesurfacenanobubblestory:Whatisinthebubble Whydoesitexist[J].AdvancesinColloidandInterfaceScience,2015,222:573-580.
[41]DUCKERWA.Contactangleandstabilityofinterfacialnanobubbles[J].Langmuir,2009,25(16):8907-8910.
[42]BORKENTBM,BEERSD,MUGELEF,etal.Ontheshapeofsurfacenanobubbles[J].Langmuir,2010,26(1):260-268.
[43]LIUYW,WANGJJ,ZHANGXR,etal.Contactlinepinningandtherelationshipbetweennanobubblesandsubstrates[J].JournalofChemicalPhysics,2014,140(5):054705.
[44]BROTCHIEA,ZHANGXH.Responseofinterfacialnanobubblestoultrasoundirradiation[J].SoftMatter,2011,7(1):265-269.
[45]ZHANGX,CHANDYC,WANGD,etal.Stabilityofinterfacialnanobubbles[J].Langmuir,2013,29(4):1017-1023.
[46]LOHSED,ZHANGX.Pinningandgasoversaturationimplystablesinglesurfacenanobubbles[J].PhysicalReviewE,2015,91(3):031003.
[47]PENGH,BIRKETTGR,NGUYENAV.Originofinterfacialnanoscopicgaseousdomainsandformationofdensefaslayerathydrophobicsolid-waterinterface[J].Langmuir,2013,29(49):15266-15274.
[48]WEIJSJH,SNOEIJERJH,LOHSED.Formationofsurfacenanobubblesandtheuniversalityoftheircontactangles:Amoleculardynamicsapproach[J].PhysicalReviewLetters,2012,108(10):104501.
[49]BRENNERMP,LOHSED.Dynamicequilibriummechanismforsurfacenanobubblestabilization[J].PhysicalReviewLetters,2008,101(21):214505.
[50]SEDDON,JAMESRT,ZANDVLIETY,etal.Knudsengasprovidesnanobubblestability[J].PhysicalReviewLetters,2011,107(11):116101.
[51]PETSEVND,SHELLMS,LEALLG.Dynamicequilibriumexplanationfornanobubbles-unusualtemperatureandsaturationdependence[J].PhysicalReviewE,2013,88(1):1-5.
[52]STOCKELHUBERKW,RADOEVB,WNGERA,etal.Ruptureofwettingfilmscausedbynanobubbles[J].Langmuir,2004,20(1):164-168.
[53]SIMONSENAC,HANSENPL,KLOSGENB.Nanobubblesgiveevidenceofincompletewettingatahydrophobicinterface[J].JournalofColloidandInterfaceScience,2004,273:291-299.
[54]TAODP,WUZX,SOBHYA,etal.Investigationofnanobubbleenhancedreverseanionicflotationofhematiteandassociatedmecha-nisms[J].PowderTechnology,2021,379:12-25.
[55]HAMPTONMA,NGUYENAV.Nanobubblesandthenanobubblebridgingcapillaryforce[J].AdvancesinColloidandInterfaceScience,2010,154(1/2):30-55.
[56]ZHANGD,MAFY,TAOYJ.Studyoneffectofnanobubbleonultra-fineflakegraphite(UFG)flotation[J].ParticulateScienceandTechnology,2023,41(7):1062-1070.
[57]MEYERC,DEGLONJ.Particlecollisionmodeling-Areview[J].MineralsEngineering,2011,24(8):719-730.

期刊导读

纳米气泡的发展历程及其稳定性研究进展

基金项目：

详细信息：

Development history of nanobubbles and the research progress on their stability

摘要:

关键词:

Abstract:

Keywords:

PDF预览

联系方式

快速导航