材料期刊网

晶化对Co43Fe20Ta5.5B31.5非晶合金磁性能的影响

袁子洲 , 包石磊 , 佟亚东 , 姚林

稀有金属材料与工程

采用单辊甩带法制备了Co43Fe20Ta5.5B31.5非晶合金薄带,利用差热分析、X-射线衍射以及振动样品磁强计研究了等温晶化和非等温晶化条件下晶化对显微组织和磁性能的影响.结果表明,等温晶化时,饱和磁感应强度Ms和矫顽力Hc都随晶化体积分数α的增加而增加.经过928 K保温55 min的晶化处理以后,合金的Ms值由制备态的37.2增加到58.4 A·m2/kg,与此同时矫顽力也由制备态的1.25×79.6 A/m增加到634.45×79.6 A/m.当只有(Co, Fe)21Ta2B6相析出时,Hc和Ms的增加幅度都比较小.随着晶化的进行,当晶体相(Co,Fe)3B2和(Co,Fe)B析出时Hc和Ms都发生突然增高.在非等温晶化条件下,Ms随终止温度的提高而单调增大,但增加幅度很小.Hc随终止晶化温度的提高而变化的幅度较大,并且变化非单调.在第1个晶化峰温度范围之内时,Hc随终止温度升高而提高,但终止温度高于第2个晶化峰结束温度时,矫顽力又急剧下降.终止温度从968 K提高到1153 K时,Ms从61.74增加到67.7 A·m2/kg, 矫顽力由267.6×79.6增加到416.2×79.6 A/m.当终止温度进一步提高到1273 K时,矫顽力又下降为152.2×79.6 A/m.

关键词: 钴基合金 , 非晶合金 , 晶化 , 磁性能

稀土Y对Co43Fe20Ta5.5B31.5合金的非晶形成能力及性能的影响

袁子洲 , 张大鹏 , 陆叶 , 包石磊 , 佟亚东

稀有金属材料与工程

采用单辊甩带和铜模吹铸法,制备了(Co43Fe20Ta5.5B31.5)100-xYx(x=0.5,1,1.5,2,2.5,3)合金薄带及ф2mm的圆棒.X射线衍射及差热扫描量热分析表明:当x=3时合金具有最大的玻璃形成能力,可以很容易地制备出ф2 mm的非晶圆棒.该成分合金的约化玻璃转变温度Trg=0.657,参数γ=0.436,在所研究的系列成分中是最大的,这说明Trg和γ能够很好地表征Co-Fe-Ta-B合金的玻璃形成能力.压缩试验和磁滞回线测试表明,Y的添加导致Co-Fe-Ta-B非晶合金的压缩断裂强度和软磁性能急剧下降.ф2 mm的(Co43Fe20Ta5.5B31.5)97Y3非晶圆棒的压缩断裂强度为1852 Mpa,断裂应变为0.18%.与Co43Fe20Ta5.5B31.5非晶合金相比,(Co43Fe20Ta5.5B31.5)97Y3非晶合金的磁滞回线上存在约327×79.6 A/m的矫顽力,同时饱和磁感应强度也显著下降.

关键词: 稀土元素Y , 微合金化 , 钴基非晶合金 , 玻璃形成能力 , 性能

辽宁小佟家堡子金矿床地质特征及成因研究

刘红霞 , 孔含泉 , 杨言辰

黄金 doi:10.3969/j.issn.1001-1277.2006.05.004

小佟家堡子金矿床位于辽吉古元古代裂谷中部的青城子矿集区内,矿体赋存于辽河群大石桥组上部碳酸岩与片岩的过渡带,容矿岩石为黑云变粒岩和硅质岩,矿体受层位控制,呈层状、似层状产出;矿石中的金以不可见金为主,含量与黄铁矿、毒砂关系密切.对矿石组构特征研究表明,该矿床形成既与沉积作用有关,又遭受后期变质变形及热液的叠加改造,矿床为热水沉积-变质热液改造成因.

关键词: 热水沉积-变质热液改造型金矿床 , 地质特征 , 小佟家堡子金矿床

辽宁小佟家堡子金矿床主要硫化物矿物特征及其成因意义

王宝林 , 代军治 , 秦丹鹤 , 王可勇

黄金 doi:10.3969/j.issn.1001-1277.2012.02.005

辽东小佟家堡子金矿床为一产于元古代辽河群大石桥组变质地层中大型蚀变岩型矿床,矿体的产出主要受大石桥组不同岩性地层之间发育的层间破碎带构造控制.金矿化以浸染、细脉浸染状产出方式为主.矿石中主要金属硫化物矿物为黄铁矿,次为毒砂、方铅矿及闪锌矿.不同时期形成的矿物其产状有一定区别.电子探针分析结果表明,黄铁矿、毒砂为主要的载金矿物,根据硫化物矿物产状及含金性特点,提出了矿床为沉积-变质并经后期热液叠加改造成因的认识.

关键词: 硫化物矿物 , 矿床成因 , 小佟家堡子金矿床 , 辽宁

辽宁青城子地区金、银矿床地质特征及其成因

郝通顺 , 王可勇 , 朴星海 , 万多 , 杨言辰 , 边红业

黄金 doi:10.3969/j.issn.1001-1277.2011.01.006

对辽宁青城子地区近年来发现的高家堡子银矿床及小佟家堡子金矿床地质特征及矿床成因进行了对比研究,结果表明两类矿床是在早期沉积-变质基础上,经历了后期热液叠加改造作用的结果,其中印支期岩浆热液活动导致了小佟家堡子等金矿床形成,而其后的大气降水活动是导致高家堡子银矿床富集成矿的主要机制.

关键词: 青城子地区 , 高家堡子银矿床 , 小佟家堡子金矿床 , 地质特征 , 矿床成因

辽宁尖山沟金矿床地质特征及成因探讨

刘培栋 , 杨言辰 , 王秀福 , 董立军 , 刘德军

黄金 doi:10.3969/j.issn.1001-1277.2007.08.005

尖山沟金矿是辽宁省有色地质局在近期评价的大型金矿床,是继找到小佟家堡子金矿后的又一个重大找矿成果.本文阐述了尖山沟金矿床地质特征及地球化学特征,并探讨了矿床成因.

关键词: 矿床地质特征 , 地球化学特征 , 矿床成因 , 尖山沟金矿床

以天然沥青岩为原料制备高压缩强度的泡沫炭

新型炭材料 doi:10.1016/S1872-5805(13)60071-2

以安纳托利亚东南部的天然沥青岩为原料制备泡沫炭.所制泡沫炭的平均孔径和密度分别为150 μm和800 kg/m3.主要研究了压力、温度、泄压时间及在最高温度时的停留时间对泡沫形成的影响,同时还评价了炭化过程对泡沫结构的影响.主要研究了压力、温度、泄压时间及在最高温度时的停留时间对泡沫炭进行了表征,并进行了密度及抗压强度分析.结果表明,1 323 K炭化后,泡沫炭压缩强度由10 MPa增加到18.7MPa.沥青的灰分含量(41.76％)对泡沫炭的密度和压缩强度起重要作用.

关键词: 泡沫炭 , 沥青岩 , 压缩强度

ATOMIC FORCE MICROSCOPY OBSERVATION OF MAGNETRON SPUTTERED ALUMINUM-SILICON ALLOY FILMS

金属学报(英文版)

粒裕希停桑谩。疲希遥茫拧。停桑茫遥希樱茫希校佟。希拢樱牛遥郑粒裕桑希巍。希啤。停粒牵危牛裕遥希巍。樱校眨裕裕牛遥牛摹。粒蹋眨停桑危眨停樱桑蹋桑茫希巍。粒蹋蹋希佟。疲桑蹋停?##2##3##4##5ATOMICFORCEMICROSCOPYOBSERVATIONOFMAGNETRONSPUTTEREDALUMINUM-SILICONALLOYFILMSJ.W.Wu,J.H.FangandZ.H.Lu(NationalLaboratoryofMoleculeandBiomoleculeElectronics,SoutheastUniversity,Nanjing210096,ChinaManuscriptreceived27October1995)Abstrcat:Twodifferentsurfacemorphologycharacteristicsofmagnetronsputteredaluminumsilicon(Al-Si)alloyfilmsdepositedat0and200℃wereobservedbyatomicforcemicroscopy(AFM).Oneisirregularlyshapedgrainsputtogtheronaplane.TheotherisirregularlyshapedgrainsPiledupinspace.Nanometer-sizedparticleswithheightsfrom1.6to2.9nmwerefirstobserved.Onthebasisoftheseobservationsthegrowthmechanismofmagnetronsputteredfilmsisdiscussed.Keywords:magnetronsputtering,Al-Sialloy,surfacemorphology,atomicforcemicroscopy,filmgrowthmechanism1.IntroductionTheuseofaluminumalloys[1,2],inparticularAl-Si,isacommonfeatureinmanysinglelevelandmultilevelinterconnectionschemesadoptedinthemanufactureofmicroelectronicdevicesbecauseofseveraldesirableproperties.TheAl-Sigrainmorphology(size.geometryanddistributionofgrainsisassociatedwithstepcoverage[3],electromigration[4]andinterconnectsresistivity[5]etc..Thus,characterizationofAl-Sialloysurfacemorphologyisveryimportant,especiallywhenintegratedintensityincreasesandlinewidthsof0.3to0.5μmbecomecommon.Inthepasttwentyyears,theAl-Sialloysurfacemorphologywhichaffectsthereliabilityofmicroelectronicdeviceshasbeenwidelyinvestigatedbyscanningelectronmicroscopy(SEM),transmissionelectronmicroscopy(TEM)etc.[5-7].However,SEMandTEMhavetheirlimitationorinconvenience,forexample,theverticalresolutionofSEMisnothighandTEMneedscomplexsamplepreparation.Recently,anewgrainboundaryetchingmethodwasproposed￣[8]whichalsoneedstroublesomechemicaletching.Atomicforcemicroscopy(AFM),sinceitsemerging,hasbecomemoreandmoreusefulinphysics,chemistry,materialsscienceandsurfacescience,becauseofitshighresolution,easeofsamplepreparationandrealsurfacetopography.Recently,discussion[9,10]waspresentedonhowAFMwillplayaroleinsemiconductorindustry.Asaresponsetothisdiscussion,weusedAFMtoinvestigateAl-SialloysurfacemorphologyandhaveobtainedsomeresultswhichcannotberevealedbySEMorTEM.ThisindicatesthatAFMisagoodcharacterizationtoolinsemiconductorindustry.2.SamplePreparationInourexperiments,aluminumwith30ppmsiliconwassputteredonsiliconsubstrateinbatchdepositionmodeAllthreefilmswiththicknessof1.6μmweredepositedusinganargonsputteringpressureof4.2×10￣-3Pa.TheotherdepositionparametersaredescribedinTable1.Thesubstratewascleanedusingstandardpremetallizationcleaningtechniquespriortofilmdeposition.3.ExperimentalResultsandDiscussionTheAFMmeasurementswereperformedonacommercialsystem(NanoscopeIII,DigitalInstruments,SantaBarbara).Thetipismadeofmicrofabricatedsiliconnitride(Si_3N_4)Itisattachedtoa200μmcantileverwithaforceconstantofabout0.12N/m.Beforethesurfaceofsamplewasexamined.agoodtipwithananometer-sizedprotrusionatitsendwasselectedbeforehand,whichcanbeobtainedbyimagingtheatomicstructureofmicasubstrateandagoldgrid.AtypicaloperatingforcebetweenthetipandAl-Sisamplesurfaceisoftheorderof10￣-8Nandallimagesweretakenatroomtemperatureinair.AtypicaltopographicviewoftheAl-SifilmsisshowninFig.1(allimagescansizeis5by5μma,bandcarerespectivelyforsample1,2,and3).FromFig.la,itcanbeseenthatirregularlyshapedgrainstiltinginvaryingdegreespileupinspace,andgroovesamongtheirregularlyshapedgrainsaredifficulttodecideatacertainarea(wedefineitascharacteristicA).Toourknowledge,onreportsonthesurfacemorphologyhavebeenpresentedbefore.InFig1b,however,irregularlyshapedgrainsassembleonaPlaneandgroovesamongtheirregularlyshapedgrainsareeasytodecide(wedefineitascharacteristicB),whichisinagreementwithmanypreviousreports[5-7].InFig.1c,bothcharacteristicA(arrowA)andcharacteristicB(arrowB)wereobserved.IndoingAFMexperiments,weselectedfivedifferentscanareastobeimagedforeachsampleandfoundthatallimagesofeachsamplearerespectivelysimilartoFig.1a,bandc.Also,wenotedthatthesurfaceofinFig.1a.WethinkthatdepositionparameterswillinfluenceAl-Sisurfacemorphology,andthetiltedgrainsmaybesusceptibletomicrocracking.Byreducingthescansizeareato2by2μm(Fig.2aandb).Weobtainedmanyidenticalresultsasdescribedabove,suchasirregularlyshapedgrainsetc.Forthefirsttime,wefoundnanometersizedparticlesonirregularlyshapedgrainsurfacewhichcannotberevealedbySEMbecausethediameterofthesenanoparticlesisabout10nmandtheheightofthesenanoparticlesisintherangeof1.6to2.9nm.Inimaging,wenotedthatrotatingthescandirectionandchangingthescanfrequencydidnotaffectthestructureofthesegrainsasshowninFig.2aandb,rulingoutthepossibilitythatscanninginfluencedtheshapeoftheseparticlesorcausedsomesimilarimagingartifacts.Also,wenotedthatthenanoparticleswerenotobservedontheslopesofthegrooves(Fig.2aandb).Thisphenomenoncanbeexplainedasfollows:thepotentialenergyattheslopeislargerthanthatelsewhere,sotheparticlesseemmorelikelytobedepositedontheseareaswithlowerpotentialenergy.Fig.2c,scansize250by250nm,isazoomtopographicimage(whiteoutlineinb).Itshowsunevendistributionofthenanoparticles.Andtheheightdifferenceofthenanoparticlesindicatesdifferentgrowingspeed.Wethinkbasedonthemorphologyofnanoparticles,thattheheightdifferenceandunevendistributionofthesenanoparticlesshowdifferentgrowingadvantageandindicatethatatomshaveenoughenergytomovetoasuitablegrowingspot.Theenergymaybefromthefollowingsources:surfacetemperaturefluctuation,stressdifferenceorcollisionbetweenhighspeedsputteredatoms.Thesenanoparticlesgoongrowingandformmanyirregularlyshapedgrains.AndtheseirregularlyshapedgrainsfurtherconnecteachotheraccordingtocharacteristicAorB,finallyformingtheAl-Sisurfacemorphology.4.ConclusionWecandrawthefollowingconclusionsfromtheabove.First,theexperimentalresultsshowedthatAFMisapowerfultooltoinvestigatethedetailsofAl-Sisurfacemorphologywhichcangreatlyenrichourknowledgeofthefilmgrowthmechanism.Second,depositionconditionsplayanimportantroleindeterminingtheAl-Sisurfacemorphology.Third,thetwoAl-Sisurfacemorphologycharacteristicsarethatirregularlyshapedgrainsassembleonaplaneandirregularlyshapedgrainstiltinginvaryingdegreespileupinspace.Fourth,forthefirsttime,nanoparticleswereobservedonirregularlyshapedgrainsurfacewhichsuggestedthatthefilmgrowthmechanismwasbyinhomogeneousnucleation.Acknowledgements-BeneficialdiscussionswereheldwithDr.ZhenandMr.Zhu.ThisworkwaspartiallysupportedbytheNationalNaturalScienceFoundationofChina.RFFERENCES｜｜1D.pramanikandA.N.Saxena,SolidStateTechnol.26(1983)127.2D.pramanikandA.N.Saxena,SolidStateTechnol.26(1983)131.3D.pramanikandA.N.Saxena,SolidStateTechnol.33(1990)73.4S.S.IyerandC.Y.Worg,J.Appl.phys.57(1985)4594.5J.F.Smith,SolidStateTechnol.27(1984)135.6D.GerthandD.Katzer,ThinSolidFilm208(1992)67.7R.J.WilsonandB.L.Weiss,ThinSolidFilm207(1991)291.8E.G.Solley,J.H.Linn,R.W.BelcherandM.G.Shlepr,SolidStateTechnol33(1990)409I.SmithandRHowland,SolidStateTechnol.33(1990)53.10L.Peters,SemiconductorInternational16(1993)62.##61D.pramanikandA.N.Saxena,SolidStateTechnol.26(1983)127.2D.pramanikandA.N.Saxena,SolidStateTechnol.26(1983)131.3D.pramanikandA.N.Saxena,SolidStateTechnol.33(1990)73.4S.S.IyerandC.Y.Worg,J.Appl.phys.57(1985)4594.5J.F.Smith,SolidStateTechnol.27(1984)135.6D.GerthandD.Katzer,ThinSolidFilm208(1992)67.7R.J.WilsonandB.L.Weiss,ThinSolidFilm207(1991)291.8E.G.Solley,J.H.Linn,R.W.BelcherandM.G.Shlepr,SolidStateTechnol33(1990)409I.SmithandRHowland,SolidStateTechnol.33(1990)53.10L.Peters,SemiconductorInternational16(1993)62.##A##BATOMIC FORCE MICROSCOPY OBSERVATION OF MAGNETRON SPUTTERED ALUMINUM-SILICON ALLOY FILMS$$$$J.W.Wu,J.H. Fang and Z.H.Lu (National Laboratory of Molecule and Biomolecule Electronics,Southeast University,Nanjing 210096, China Manuscript received 27 October 1995)Abstrcat:Two different surface morphology characteristics of magnetron sputtered aluminumsilicon(Al-Si)alloy films deposited at 0 and 200℃ were observed by atomic force microscopy(AFM).One is irregularly shaped grains put togther on a plane.The other is irregularly shaped grains Piled up in space. Nanometer-sized particles with heights from 1.6 to 2.9 nm were first observed. On the basis of these observations the growth mechanism of magnetron sputtered films is discussed.

关键词: :magnetron sputtering , null , null , null , null