Preparation and Characterization of Magnetic Glass ... · Characterization of Magnetic Glass Ceramics Derived from Iron Oxides Bearing Rolling Mill Scales Wastes. Nano Res Appl. 2015,
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IntroductionThepropertiesofnanomaterialsarenotwellunderstoodalthoughthey have been in use for centuries. Early Chinese dynastyporcelain glazes were the earliest application [1]. During theRenaissanceperiod,artistsinUmbria,Italyutilizednanomaterialsin art fabrication [2]. Several decades ago, serious researchonnanotechnologybegan[1].Sincethen,significantimprovementshavebeenmadeonprocessdevelopmentofnanomaterialswithcontrolledstructureandproperties[1].Recently,one-dimensional(1D)andquasi-one-dimensional(Q1D)materialswithmagneticphaseshaveattractedgreatattentionduetotheirpotentialsasbuildingblocksforfutureelectromagneticdevices[3,4].
Theneedforwasterecyclingisimportantasscientistscontinueto seekways to reduce theenvironmental impact of industrialwastes. Industrialwaste has been amajor sourceof air,waterandindustrialpollutionresultingfromsolidwastedisposal.Thisconsequently has a negative impact on the environment withincreasedassociatedcosts.Owingtothegrowingamountofsolidwastes produced by industrial firms, increased environmentalregulations and the need for pollution abatement, there isincreasedinterestinusingrecyclingasameansofdivertingsolidwastestousefulproductsasglass-ceramics.
The following are examples for producing glass ceramics fromsolidwastes.Blast-furnaceslagwasthefirstsilicatewastetobe
Preparation and Characterization of Magnetic Glass Ceramics
Derived from Iron Oxides Bearing Rolling Mill Scales Wastes
AbstractRollingMillScales(RSW)wereusedasrawmaterialsforpreparationofhardandsoftmagnetic glass ceramicswhich have awide range of applications. In steel processingup to5%ofsteel is lostwithscalesduring thehot rollingoperationwhereIronoxidesform~69-72%ofthemillingscalesweight.Inadditiontotheironcontent,millscalesarecontaminatedwithremainsoflubricants,oilsandgreasefromtheequipmentassociatedwithrollingoperations.Theoilcontenttypicallyrangesfrom0.1and2%-butcanreachupto20%-beside~10%water.ThegoalofthisprojectwastoevaluatemagneticpropertiesofsoftandhardmagneticglassceramicssynthesizedfromRSW. Tosynthesizesoftmagneticglassceramics(SMGC)andhardmagneticglass ceramics (HMGC),65wt%and37wt%respectivelyofRSWwereused.Quenching-meltingtechniquewasutilized.Differentialthermalanalysis(DTA)showedonebroadexothermicpeakat906ºCandat731ºCforSMGCand HMGC respectively. For SMGC, the major detectable peaks belong to Zn-ferrite(ZnFe2O4)andHematite(Fe2O3)asshownbyX-raydiffraction(XRD)analysis.Alternatively,Ba-hexaferrite(BaFe12O19)andHematitearethedetectedphasesinHMGCsamples.Afterheattreatment,crystallizationof~131-166and24-34nmmagneticparticlesweredetectedforSMGCandHMGCviatransmissionelectronmicroscopy (TEM). An increase in saturationmagnetization from 18 emu/g forRSWto66.5emu/gforheattreatedSMGCand19emu/gforHMGCwasmeasuredwithaVibratingScanningMagnetometer(VSM).Theresultsconfirmthatwewereabletorecyclerollingmillscalesintohardandsoftmagneticglassceramicswithmagneticphasecontentreaches92.4wt%.Keywords:Rollingmillscales;Glass-ceramics;Nanoparticles;Ferrimagnetism;Zn-ferriteandBa-hexaferrite
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investigatedasasourcematerialforglassceramics.Theseslagsconsist of CaO, SiO2 and MgO as the main constituents, withminorconstituentssuchasMnO,Fe2O3andS.ThefirstattempttocommercializeaglassceramicfromslagwasbytheBritishIronandSteelResearchAssociationinthelate1960’s[5].Fabricationof glass-ceramics using slag-type wastes from non-ferrousmetalproductionhasbeenreported,these includecopperslag[6,7]andphosphorusslag[8].Upto40wt%ofcopperslagwasincorporated into a base glass composition to produce tilesvia thepowder sinteringmethod [6].Mixturesof coal ashandwaste glass have been used in early technological approachesto fabricate glass ceramics and glass matrix composites usingpowdertechnologyandsintering[9-11].Chenget al. conductedsingle-step heat treatment of glasses obtained from vitrifiedincineratorflyash [12]andofamixtureofelectricarc furnace(EAF)dustandflyash[13].
MPelinoetal.[14]andMorsietal. [15] preparedglassspecimensbymeltingmixturesofmagnesite, feldspar,quartz sand,kaolinand cement dust with dust content in the range 25–37 wt%.Gorokhovskyetal.[16]produceddiopside-basedglassceramicsbasedonacombinationofawiderangeofwastes(quartz-feldsparwaste,limestonedust,phosphorusslurry,metallurgicalslag)andselected commercially available chemicals, such as Cr2O3, as a nucleatingagent.Yunetal.[17] preparedglass-ceramicsfromamixtureoffluorescentglassandwasteshellinaweightratioof4:1.Diazetal.[18]recentlyreportedthatitispossibletoproducecordierite glass-ceramics from inorganic wastes of anodizingplants. Reusing jarosite and goethite from hydrometallurgicalprocesses toobtainglassandglass-ceramicmaterialshasbeenreportedinseveralpapers[19-25].
Rollingmill scales are solid by-products from the steelmakingindustry that contain metallic iron and three types of ironoxides: Wustite, Hematite and magnetite. Rolling mill scalesalso contain traces of non-ferrousmetals, alkaline compoundsand oils from the rolling process [26]. Mill scales are formedon theouter surfaces of plates, sheets or other configurationsproducedby rolling red-hot ironor steel billets in rollingmills.Mill scaleswithbluishblackcolorarecomposedof ironoxidesmostlyferric(Figure 1).Inthewholeworld,13.5milliontonsofmillscalesaregeneratedannually[27].Dependingontheprocessandthenatureoftheproduct,theweightofmillscalecanvarybetween20and50kg/tofthehotrolledproduct.Theaveragespecificproductionofthisby-productistypically35-40kg/t[28].Approximately90%ofmill scales isdirectly recycledwithin thesteelmakingindustryandsmallamountsareusedforferroalloys,in cement plants and in the petrochemicals industry [29-32]. Volodymeret.al.[26] utilizedtherollingmillscalesintheironoresinteringprocessastheywereabletoimprovethecombustionofthescale’soilatthesinteringprocessbypreparationofamixturewithpeat.By theirmethod theconsumptionof theoiledscalewas increased from zero to 12.8 kg. A studywasmade byMIMartinet.al. [28]of thereductionofmill scale tosponge ironusingcokeatdifferenttemperatures.N.M.Gaballahet.al.,[33] preparedtwomodelsfortheproductionofironfromrollingmillscaleswastes via hydrogen reduction at varying temperatures.
Reintroducing the rolling mill scales into an industrial processthroughwellplannedprogramswillreducetheirenvironmentalimpactandwillimprovecostsavings.
Glass-ceramicsaredefinedascompositematerials thatcontainat least one crystalline phase dispersed in an amorphousglassymatrix. The chemical compositionof theglassprecursorinfluencesthephysicalandchemicalpropertiesofthecomposite.Therefore, the investigation of new composite glass materialswithcontrolledparticlessizedistributionandaspectratiohasanimpact on industry. Preparation of magnetite-containing glassceramics has been reported by several groups [34-36] whereferromagneticbioglass-ceramicscontaining45wt%ofmagnetitewereprepared[37]andabout60wt%werereportedbyothers[38,39]. Traditional compactmagneticmaterials are commonlyprepared by sintering of ferrite powders [40,41] with a meanparticlesizeofabout1µmat1200-1250°C.Duringsinteringthemagnetic crystals grow so that multi-domain behavior occurswhichlowersthecoercivityofthematerial[42].
Spinelandhexa-ferritesarealargeimportantclassofmaterialswiththegeneralformulaM-Fe2O4forspinelferritesandM-Fe12O9forhexa-ferrites,whereMisadivalentcation.Hexa-ferriteshaveahexagonalcrystalstructurewherethemagneticpropertiesofthespinel ferrites originatemainly from themagnetic interactionsbetweencationswithmagneticmoments,whicharesituatedintetrahedralandoctahedralsites[43-45].Thepreparedmaterialshavewidespreadapplicationsinmaterialscience[40,46-51]andbiotechnology[38,39,52].
Inthisstudy,glasstechniqueswereusedtoprepareacompactbody inwhichmagneticparticleswerewelldispersedandkeptinsingledomainbehavior.Wepreparedcompactglassceramicsthat contain single domain particles (<100 nm) separated bya nonmagnetic matrix which lowers the sinter temperature,prevents theparticles fromgrowing tobe inmulti-domainandresulted in low magnetic interaction. The main objective ofthis research was to evaluate RSW from various metallurgical
industries and to prepare soft and hard nanomagnetic glass-ceramics.
Thesenanomagneticglass-ceramicshavepotential applicationsin health care such as cell separation, magnetic resonanceimaging contrast agents [53], drug delivery, tissue engineeringandhyperthermiatreatmentofcancer.Inaddition,theyhaveawiderangeofapplications in informationstoragesystems [54],ferrofluidtechnology[55,56],magnetocaloricrefrigeration,gas-sensorsandcatalysis[57].
Experimental MethodsPreparation of the glassX-Ray Fluorescence (XRF) analysis was used to determine thecomposition of the RSW samples as illustrated inTable 1. Thesamples were preparedwith two compositions: one based oncrystallizationofZnFe2O4asasoftmagnetandtheotherbasedonBaFe12O19asahardmagnet.Thecompositionsofthepreparedsamples are reported inTable 2. RS and RH are soft and hardmagneticreferencesamplespreparedfrompurechemicalssuchasZnCO3, Na2CO3,NH4H2PO4,TiO2,BaCO3,H3BO3andSiO2.SMGCrefers to softmagnetic glass ceramics that contain about 65%ofRSWwhileHMGCreferstohardmagneticglassceramicsthatcontain~37%ofRSW. Small amountsof ZnOas ZnCO3, Na2O asNa2CO3,P2O5asNH4H2PO4,TiO2,BaOasBaCO3andB2O3asH3BO3 were added to complete the design of the desired phases.Aspreviously described (Salwa A. M. Abdel-Hameed et al. 2014)the samples were prepared by melting the required amountsofreagentgradechemicalswithcompositionshowninTable 2.Sampleswerepreparedinplatinumcruciblesat1500ºCforsoftferritesamplesand1200ºCforhardferrites,andheatedfor2hinelectricallyheated furnacewithoccasional swirlingevery30min toensurehomogenization. Themeltswerepouredontoastainless steelplate in1-2mmthickstripsbyapplyinganothercoldsteelroller.
Characterization
Todetermine the temperaturesof theglass transition (Tg) andcrystallization(Tc)oftheglasssamplesdifferentialthermalanalysis(DTA;SDTQ600)underinertgaswithaheatingrateof10oC/minwasused.Aluminawasusedastheinertreferencematerial.Theresultsobtainedservedasaguidefordeterminingtherequiredheat-treatmenttemperaturesneededtoinducecrystallizationinthesamples.To investigatetheeffectofheattreatmentonthephasetransformationandsampleproperties,sampleswereheattreatedat900oCfor2h.SamplesbeforeandafterheattreatmentwereevaluatedusingpowderX-raydiffractionusingaNi-filledCu-Kαtargettoidentifytheircontentandtheprecipitatedcrystallinephases. X-raydiffraction (XRD)wasperformedusingBrukerD8Advanced instrument (Germany D8 ADVANCE Cu target 1.54A, 40 KV, 40mA). The reference data for the interpretationofthe XRD patterns was obtained from ASTM X-ray diffractioncard files. Samples were crushed and sonically suspended inethanol.A fewdropsof thesuspendedsolutionwasplacedonanamorphouscarbonfilmheldbyacoppermicrogridmesh. The microstructureandcrystallitesizewascharacterizedusingaTEM2010 transmission electron microscope. Chemical compositionofthecrystalsintheglassceramicswereanalyzedbyEDXusingOxford instrument INCAX-sight on a Joel TXA-840A electronprobemicro analyzer. Themagneticpropertieswere evaluatedwithavibratingsamplemagnetometer(VSM,9600-1LDJ,USA)inamaximumappliedfieldof20KOe.Saturationmagnetization(Ms), remanance magnetization (Mr) and coercivity (Hc) weredeterminedfromthehysteresisloops.
Results and DiscussionsDifferential thermal analysisThe DTA scan provides a rapid method to investigate thecrystallization nature, the effect of heat and the temperaturerangeofcrystallizationandtheproperheat-treatmentschedule.Thelimitsofcrystallizationhowever,areabout±30°CoftheDTAcrystallization peaks; as with powdered glass samples, surfacenucleation and devitrification tend to obscure the internalstructuralchangesoftheglass[58].
DTAofRS,SMGC,RHandHMGCsamplesbeforeheattreatmentare shown in Figure 2. The materials resemble a crystallinestate.When the amorphous state decreases, the endothermicand exothermic intensities decrease. In general, DTA resultsshow lower intensity thermal effects due to the high degreeof crystallization during cooling from melting temperature toroom temperature. DTA results show an endothermic effectresemblinganamorphousphaseat657ºCforRS,642ºCforSMGCsample,551ºCforRHandabout516ºCforHMGCsample.Thisendothermicreactionisbelievedtobecausedbyanincreaseinheatcapacityduetotransformationofglassfromarigidtoplasticstructureandtheaccompaniedrearrangingofdifferentatomsasaprecrystallizationstep[59]. Theendothermictemperaturesarelower in thebatchcompositionscontainingRSWthan thoseofpurechemicalsduetotherefluxeffectofdifferentoxidespresentinRSWwhichlowerthesamplesviscosityandTgasshowninTable 2.Thesharpendothermiceffectat90oCinSMGCwasattributedtowaterevaporationwhilethebroadexothermicpeakat906ºCisanindicationforcrystallizationofbothhematiteandZn-ferrite
Main Constituents (wt,%)SiO2 1.33TiO2 0.03Al2O3 0.45Fe2O3
Alternatively,asingleexothermappearedat731oCfortheHMGCsample and two exothermic peaks at 611oC and 737oC in RHsamplecorrespondingtoBa-hexaferritecrystallization.Theshapeand intensity of the exothermic peak are a good indicator forthecrystallizationprocess;thesharperandstrongerexothermicpeakreflectslargerandquickercrystallization,conversely,iftheexothermic peak is broad, the crystallization is slow and small [60].The DTA results were used to determine heat treatmentschedulewhichwasappliedtosamplesat900oCfor2htostudyitseffectonthecrystallizationprocess.
ThemajordetectablepeakscanbeindexedtoZn-ferrite(ZnFe2O4)and Ba-hexaferrite (BaFe12O19) for SMGC and HMGC samplesrespectively.Thesedesignedcompositionsucceededinreachingthetargetedphases.SeveralfactorscontributetothebroadeningofpeaksinX-raydiffraction[60,61].Forexample,factorsrelatedtotheresolutionandtheincidentX-raywavelengthoftheXRD,aswellasthesamplecrystallitesizeandnon-uniformmicrostrain,can cause a line broadening. In the case of an instrumentalbroadening, the line width will vary smoothly with 2θ or dspacing.Ontheotherhand,thelinebroadeningoriginatingfromthesamplecharacteristicswillhaveadifferentrelationship. Using Scherrer'sequation[62,63]forcrystallitesizeandtheBragg'slawfordiffraction [64], crystallite sizeandmicrostrain componentsareestimated:
• TheSchererequationis:K =
cos λ
τβ θ
where:
• is themean size of the ordered (crystalline) domains,whichmaybesmallerorequaltothegrainsize;
• K is a dimensionless shape factor,with a value close tounity.Theshape factorhasa typical valueofabout0.9,butvarieswiththeactualshapeofthecrystallite;
λistheX-raywavelength;
βisthelinebroadeningathalfthemaximumintensity(FWHM),after subtracting the instrumental line broadening, in radians.ThisquantityisalsosometimesdenotedasΔ(2θ);
θistheBraggangle.
• Bragg'slawis: 2 sin d n=θ λwhere
• nisapositiveinteger
λisthewavelengthofincidentwave
disthespacing
Figure 3aillustratesthedifferencebetweenRSWandSMGCbeforeandafterheattreatment.TheRSWsamplesincludeHematiteandMagnetitephaseswithtraceWuestitephasewhichdisappearedcompletely in SMGC. Furthermore, applying heat treatment at900°Cfor2haffectedthecrystallizationofZn-ferriteasauniquephase.Comparingthemainpeaksinthethreepatternswenoticethat heat treatment has a greater effect on crystallization andamountofZn-ferritecrystallized.TheXRDspectrarepresentthecrystallizationofZn-ferriteasasinglephaseinRSsample(Figure 3b ),withlesscrystallizationrelativetoSMGCsample.TheamountofZn-ferritedecreasedintheRSsampleafterheattreatmentat900oCfor2hduetotheseparationofSiO2phase.ComparingthecompositionsofRSandSMGC, it’sevident that thereareextraoxidespresentinSMGCsampleduetoRSWcompositionaslistedin Table 2.TheseoxidesfacilitatethecrystallizationofZn-ferrite
Alternatively,Figure 4bshowstheXRDspectraofHMGCbeforeand after heat treatment. Hematite, Wuestite and Zn-ferritephasespresentintheRSWsampledisappearandabroadhumpcharacterizing the amorphous glassy state appears in HMGCsamplebeforeheattreatment.Ba-hexaferritecrystallizesasthesoleformedmagneticphaseinanonmagneticmatrixwhenthesample is exposed to heat treatment at 900oC for 2 h. A cleareffectoftheheattreatmentontheRHsampleisshowninFigure 4a, with the transformation from an amorphous to crystallinestate as represented by crystallization of pure Ba-hexaferrite.MoreBa-hexaferritecrystallizedinHMGCthanintheRHwhichisreflectedbyhigherXRDpeakintensities.
Transmission electron microscopeTo investigate the possibility of micro twinning and thehomogeneity of the materials TEM was performed. Particlesizewasmeasured fromTEM images.Figure 5 shows theTEMmicrostructures inhighmagnificationforSMGC,RS,HMGCandRHsamplesbeforeandafterheattreatment.Figure 5a,5b showthe precipitation of nanosized cubic crystals of Zn-ferrite andHematite phases in the SMGC sample before heat treatmentwithcrystallinesizerangefrom131-166nm.AllHematitecrystalstransformed to Zn-ferrite after heat treatment with crystallinesize range from23-33 nm, this confirmed the results obtainedfromXRDcalculationsshowninFigure 3.TEMforRSsamplesareshown in Figure 5c, 5d which illustrates the transformation ofZn-ferrites toSiO2phasewith crystalline sizeofabout223nmafterheattreatment.Incontrast,Ba-hexaferritewithhexagonalcrystalsisformedasauniquephasewithcrystallinesizerangingfrom24-34nminHMGCsamplesafterheattreatmentasshownin Figure 4.Inaddition,TEMforRHrepresentedinFigure 5g, 5h showthecrystallizationofBa-hexaferriteasasinglephasewithcrystallinesizerangingfrom2-12nmafterheattreatment.
Magnetic propertiesFigures 6 and 7 illustrate the room temperature magnetichysteresis(M-H)loopsofSMGC,RS,HMGCandRHsamplesbeforeandafterheattreatmentunderamagneticfieldstrengthof±20KOe.Table 3 lists therelevantmagneticparameters;saturationmagnetization (Ms), coercivity (Hc), remanence (Mr) obtainedfromM-H loops. Themagnetic field necessary to saturate thesamplesincreasedwiththeincreaseinthecrystallizationofZn-ferriteinsoftsamplesandBa-hexaferriteinhardmagnets.Figure 6 illustrates thatMs increased from 18.393 emu/g for RSW, to45.175 emu/g for SMGC samples before heat treatment andcontinued increasing to 66.463emu/g afterheat treatment. Incontrast,themagnetizationofRSsamplesdeclinedfrom38.678emu/gto24.293emu/gafterbeingexposedtoheattreatmentat900°Cfor2h.Figure 7 showsthatMs increasedfrom18.393emu/g for RSW sample to 19.06 emu/g forHMGC sample andincreasedto24.19emu/gafterheattreatment.ThesametrendisshownforRHsampleswhereMsincreasedfrom8.0774emu/gto16.665emu/gafterheattreatmentfor900°C/2hrs.Asexpected,saturationmagnetizationinthesamplesisshowntobedirectlyproportionaltothedegreeandamountofcrystallizationofZn-ferriteandBa-hexaferrite.ItshouldbenotedthatZn-ferritesandBa-hexaferrite are ferromagnetic materials, whereas hematiteis an antiferromagnetic. The results show that hematite andamorphousphaseshaveaverylowsaturationmagnetization.Asaconsequence,thevariationofthesaturationmagnetizationcanbeattributedtothemodificationofthequantityofZn-ferriteandBa-hexaferritecrystals[65]presentintheglass-ceramicsamples.Therefore,themaximummagnetizationvaluesof66.463emu/gforSMGCafterheattreatmentand24.19emu/gforHMGCafterheattreatmentrefertotheheaviestandmostintenseZn-ferriteandBa-hexaferritecrystallizationofallthesoftandhardmagnetsamplesrespectively.Thequantityofthemagneticphasepresentintheglassceramicsampleswasdeterminedfromthesaturationmagnetization ratio between the sample and pure magnetite(Ms=72emu/g)[66].92emu/gisthesaturationmagnetizationof
Figure 3 XRD spectra of glass-ceramics before and after heattreatment,a)RSsamplesbeforeandafterheattreatmentandb)SMGCbeforeandafterheattreatment.
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bulkmagnetiteasreportedfromtheliterature[67],O.Bretcanuet.el. Measured the magnetite saturation magnetization as 72emu/g and they referred this decrease to the powder formofthemeasuredsamples.Surfaceeffectscanmodifythesaturationmagnetization of a magnetic material, usually lowering themagnetization.Themaximummagneticphasesaccumulation is92.4wt%forheattreatedSMGCwhichisabigincreasethanwhatpreviouslyreportedbyotherworkers[37-39].
Thecoercivityofsoftferrimagneticglassceramicsvariedbetween106.25OefortheRSWsampleand32.775OeforSMGCbeforeheat treatment with a small increase to 32.966 Oe after heattreatment.InHMGCsamplesheattreatmenthadalargereffectoncoercivitywhichincreasedfrom106.25GforRSWsampleto128.77GforthemeltedHMGCsamplesbeforeheattreatment
and increasedto425.32Gafterheat treatment.Similarly,heattreatment had a noticeable effect on the reference samplescoericivitieswith an increase from 16.756G to 193.44G afterheattreatmentofRSandincreasedfrom160.39Gto1001.5Gfor RH after heat treatment. The coericivity of a ferrimagneticmaterial is the intensityof the appliedmagneticfield requiredto reduce themagnetization of thatmaterial to zero after themagnetization of the sample has been driven to saturation.Coericivitymeasurestheresistanceofaferromagneticmaterialtobecomedemagnetized.Thewiderangeofcoericivityprovides forawiderangeofapplications.Materialswithhighcoericivity,whicharecalledhardferromagneticmaterials,areusedtomakepermanent magnets. Permenant magnets are used in electricmotors,magneticrecordingmedia(e.g.,harddrives,floppydisks,or magnetic tapes) and magnetic separation. While materialswith lowcoericivitywhichare said tobe softmagnetsmaybeusedinmicrowavedevices,magneticshielding,transformers,orrecordingheads.The retentivity is found todetect theamountofmagneticmaterialswhichcanbemagnetized[68,69],evenintheabsenceofexternalmagneticfield. Incomparisonbetweensoftandhardferrites,Table 3showsthattheretentivityofmostofthehardmagnetsislargerthanthatofthesoftmagnetsandis related to the area of the hysteresis loops. The area of thehysteresis loops of the hard ferrites is larger than the areas inthe case of soft ferrites. The area under the hysteresis loop isproportional to the energy loss and hence the heat generatedbyasampleunderanalternatingfieldandhardferritessamplesarecapableofgeneratingmoreheat.The largevariation intheareaundertheloopsforhardandsoftferritessamplesprovidesacontrolledheatgenerationbyappropriatechoiceofsample.
Conclusions• Two different ferrimagnetic glass ceramics with
• The influence of the chemical composition, the amountof Zn-ferrite and Ba-hexaferrite crystallization and themicrostructure of ferromagnetic glass ceramics onmagneticpropertiesofglassceramicswereinvestigated.
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