Preparation of Fe(II)-montmorillonite by reduction of Fe(III)-montmorillonite with ascorbic acid
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Preparation of Fe(II)-montmorillonite by reduction of Fe(III)-montmorillonite with ascorbic acid
二价铁-蒙脱土复合材料
AppliedClayScience42(2008)32–
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AppliedClayScience
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PreparationofFe(II)-montmorillonitebyreductionofFe(III)-montmorillonitewithascorbicacid
JayappaManjanna?
GraduateSchoolofEngineering,HokkaidoUniversity,Sapporo060-8628,Japan
articleinfoabstract
AnewandconvenientmethodisdescribedheretoprepareFe(II)-montmorillonite(mont)usingFe(III)-montasthestartingmaterial.Fe(III)-montwastreatedwithascorbicacid(vitaminC)solutionat70°Cfor~12hinAratmosphere.Alloftheadsorbediron(III)wasreducedtoformFe(II)-mont.ThepresenceofanyassociatedFe-oxidephaseinthestartingmaterial,Fe(III)-mont,wasratheradvantageoustoreachstoichiometricFe(II)-mont.TheFe2+/FetotalratiooftheironextractedfromfreshlypreparedFe(II)-montwasfoundtobeclosetounity.Thetotalamountofironextractedin1MNH4Clwasequivalenttothecationexchangecapacityoftheparentmontmorillonite(KunipiaFmontmorillonite)intermsofFe(II),providedtherewassuf?cientiron(III)inthestartingmaterial.Thebasalspacingatarelativehumidity(RH)of40%was14.7Å,typicalofmontmorillonitewithdivalentinterlayercations.FTIRspectrashowednosigni?cantchangesinthebasicclaymineralstructure.ThestructurewasfurtherprovedbyMössbauerspectraatroomtemperature(RT).ThusFe(II)-montpreparationasdescribedherewasfoundtobehighlyconvenientforroutinepreparationintheambientatmosphericcondition,alsoforlargequantities.Thefeasibilityofsolid-statepreparationofFe(II)-montwasalsodemonstrated.ThestabilityofFe(II)-montwasprovedindispersioninwaterunderpartiallydeoxygenatedcondition.Therewasabout30%and70%oxidationofinterlayerFe(II)ionsinabout47daysatRTand65°C.Thus,theinterlayerFe(II)ionsweregraduallyoxidized(i.e.,notrapidly,asanticipated).Forlong-timepreservationoftheFe(II)-montsample,itisessentialtokeepdeoxygenated,lowRH(b40%)conditionsandwithoutexposingtoelevatedtemperatures.
©2008ElsevierB.V.Allrightsreserved.
Articlehistory:
Received19September2007
Receivedinrevisedform30January2008Accepted11February2008Availableonline4March2008Keywords:
Fe(II)-montmorilloniteFe(III)-montmorilloniteAscorbicacid
1.Introduction
Environmentallybenignandredoxsensitivemetalions,Fe(II)andFe(III),intheinterlayerofmontmorillonitecanimpartmanytechnologicalapplications.MostoftheFe-montmorillonitesintheliteratureareconcernedwithFe(III)species(andnotferrousions)whichhavebeenstudiedforapplicationsindifferent?eldsthatincludepillaredclaysascatalysts(Zuritaetal.,1996;Palinkoetal.,1997;Kloprogge,1998;Kantametal.,1998;YamanakaandHattori,1988;Doradoetal.,2006)inorganicreactions,andadsorbentfortheremovaloftheenvironmentaltoxicants(Lenobleetal.,2002;Izumietal.,2005;Tabetetal.,2006;Masihetal.,2007).TheseFe-montmorillonitesarecommonlyobtainedbycationexchangeand/orintercalationofNa-montmorillonitewithhydrolyzedFe(III)species(HerreraandPeech,1970;Valverdeetal.,2005).IfFe(II)ionsaretheinterlayercationsofmontmorillonite,manyredoxreactionsareexpected.Sofar,onlythestructuralironofiron-richclaymineralshasbeenexplored(Stuckietal.,1984;Stucki,1988;Komadeletal.,
?PresentlyatNDEandScienceResearchCentre,FacultyofEngineering,IwateUniversity,Morioka020-8551,Japan.Tel./fax:+81196216350.
E-mailaddress:jmanjanna@http://wendang.chazidian.com.0169-1317/$–seefrontmatter©2008ElsevierB.V.Allrightsreserved.doi:
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2000;Komadel,2003;Leeetal.,2006),buttheapplicationoftheseclaymineralsseemstoberestrictedduetotherapidre-oxidationofreducedironand/ortheavailabilityofsuchredox-modi?edclaymineralsinbulkamountsunderambientatmosphericconditions.Thereareonlyafewstudies(Kameietal.,1999;Kozaietal.,2001,2007;Manjannaetal.,2007)dealingwithFe(II)-montpresumablyduetothelackofaconvenientmethodtoobtaintheFe(II)-mont.Conventionally,FeCl2couldbeusedfordirectcationexchangeunderstrictoxygencontrol(Kozaietal.,2001).However,theformationofionic-pairslikeFeCl+anditsstrongaf?nitytotheclaymineralsurface(CharletandTournassat,2005)causedchlorideimpuritiesinthepreparedsampleofFe(II)-mont(Kozaietal.,2007).Also,whilewashingthemontmorillonitetoremoveexcessFeCl2,thehydrolysis/precipitationofironcompounds(duetosuccessiveincreaseofpH)mayleadtoexcessamountsofiron.Toovercomethedif?cultiesassociatedwiththeuseofFe(II)salts,anewmethodwasproposedrecently(Manjannaetal.,2007).ThelessstableFe(II)-nitrilotriacetate(NTA)complex(logK=8.3)andnotthemorestableFe(III)-NTA(logK=15.9)facilitatedthecationexchangeofNa-montmorillonite.BulkpreparationwasnotpossiblebecauseofthecompetingprecipitationofFe(II)-NTAabove20mM(duetolowsolubility).TheexcessiveuseofNTAisharmfultotheenvironment(Fe-NTAiscarcinogenic).
Furthermore,inviewoftheclaymineralalterationduetoironcorrosionproductsinthegeologicaldisposalofnuclearwaste(JNC,
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2000;Guillaumeetal.,2004;Wilsonetal.,2006;Carlsonetal.,2007),Fe(II)-montisenvisagedasoneofthesimplestalterationproductatreducingconditions.HencethepropertiesofFe(II)-mont(suchasswelling,hydraulicconductivity,diffusionofradionuclidesetc.)areveryimportant.Forthesestudies,theavailabilityofFe(II)-montinlargeramountsisneeded.
InanefforttodevelopasimpleandenvironmentallybenignmethodforthepreparationofFe(II)-montatambientconditions,Fe(III)-montwasconvertedtoFe(II)-montthroughthereductionofinterlayer/adsorbedFe(III)ionswithascorbicacid(vitaminC)solution.
2.Materialsandmethods
WeusedNa-montmorillonite(KunipiaF,Japan)withacationexchangecapacity(CEC)~113meq/100g(Kozaietal.,1993)andapproximatechemicalcomposition,(Na0.431K0.002Ca0.002)(Al1.56Mg0.305Fe0.099Ti0.007)oct(Si3.949Al0.051)tetO10(OH)2nH2O.
Allsolutionswerepreparedusingdistilledwater(conductivity0.06μScm?1),andthechemicalswereofanalyticalreagentgrade.Theexperimentswereperformedatroomtemperature,20±3°C(RT)unlessotherwisementioned.Ar-gaswaspurgedintheappropriatesolutions.
TheconcentrationofironinsolutionsandtheFe2+/Fetotalratioi.e.,[Fe(II)/(Fe(II)+Fe(III))]wasdeterminedbytheo-phenanthrolinemethod(Bassettetal.,1978)usingaUV–Visiblespectrophotometer(λmax510nm).Insomecases,Fetotalwasdeterminedbyinductivelycoupledplasmaatomicemissionspectroscopy(ICP-AES).Forthesemeasurements,thedispersedclayparticleswereremovedbycentrifugationfollowedbyultra-?ltration(0.01μm?lter).
Forcomparison,Na-,Ca-andCr(III)-montwerealsopreparedfromKunipiaFmontmorillonitebytheconventionalcationexchangewith1MsolutionsofNaCl,CaCl2andCrCl3respectively(Kozaietal.,1996;Kozakietal.,1999;Juangetal.,2004).2.1.Startingmaterial,Fe(III)-montmorillonite
Fe(III)-montwasobtainedbycationexchangeofNa-montin0.4MFeCl3solution(pH~1.7).About10goftherawmontmorillonite(KunipiaF)wasaddedto1lof0.4MFeCl3solutionandstirredfor~24h.Thedispersionwasallowedtosettleovernightandafterdecantingthesupernatantsolution,themontmorillonitewasre-dispersedinfresh0.4MFeCl3solution,andthisprocesswasrepeatedtwice.Then,thedispersionwascentrifuged.InthecaseofFe-1,themontmorillonitewaswashedseveraltimeswithdistilledwater(~500mlofwaterper10gofclay)by?ltrationthrough0.2μm?lterpaper.FiltrationwasfoundtobemuchfasterandeasierthandialysisbecauseoftherestrictedswellingofFe(III)-mont,unlikeNa(I)-orCa(II)-mont.Fe-2waswashedwithdistilledwaterbycentrifugationtosqueezeoutmostoftheFeCl3solution,andthenwashedasinthecaseofFe-1.Duetothisdifferenceinthewashingstep,Fe-1containedhigheramountsofexternallyprecipitatedferricionsthaninFe-2,Table1.BoththesampleswerewasheduntilnoCl?wasdetectedbyAgNO3test.Theyweredriedinvacuumat25°Cforseveralhoursandthengroundtopowder.Thesampleswerestoredinvacuumdesiccatorforsubsequentuse.
ThetotalamountofadsorbedFe(III)inFe-1andFe-2wasdeterminedbyextractionwith50mMNa2EDTAsolutionat70°Cfor~24h(Table1).Thesample(≈0.5g)wasdispersedin100mlofthefreshreagentfor3timesandthecumulativeironreleasedwasconsideredasthetotaliron(Fetotal).
2.2.ConversionofFe(III)-toFe(II)-montmorillonite
ThesamplesofFe-1orFe-2were?rstdispersedinwaterfor~12hintheratioof1g/100ml.Ascorbicacidwasthenaddedandthedispersionwasstirredat~70°Cfor12hunderAr.Theascorbicacidconcentrationwasabout8and5mMrespectivelypereachgramofFe-1andFe-2basedonthecorrespondingamountsadsorbedFe(III).Themontmorillonitewasseparatedbycentrifugation,washedthoroughlywithdeoxyge-natedwater.ThecompleteremovalofascorbicacidwasensuredbytestingofsuccessivewashingsforFe(II)withferroinreagent(assumingferrous-ascorbatecomplexation).Theabsenceofascorbicacidwasalsotestedwithmixtureofiodineandstarchsolution.
Table1
Fecontentandspeci?csurfacearea(S)ofFe(III)-andFe(II)-montsamples(MB—methyleneblue)Samples
Fein
MB
Sinm2/gmeq/100g
adsorbed(mol/g)
SMBSBETFe(III)-montFe-12266.4×10?450070Fe-2
1427.8×10?461047Fe(II)-montFe-1r1208.7×10?468045Fe-2r
97
9.2×10?4
730
45
Fe(II)-montthusobtainedfromFe-1andFe-2wasdriedinvacuumat25°C,anddesignatedhereasFe-1randFe-2r(Table1).
Toevaluatethefeasibilityofsolid-statepreparation,1gofFe(III)-mont,(Fe-2)andascorbicacid(0.06g)weregroundinopenatmosphereatdifferentrelativehumidity(RH)conditions,20–80%.ThetimerequiredfortheconversionofallFe(III)toFe(II)couldbeseenfromthecolorchangei.e.,theinitialbrowncolorofthemixturebecamegrayishwhiteinafewminutesdependingonRH.Itwasfurtherestimatedbyperi-odicallydrawingaliquotofthemixtureandreactingwithasolidKSCNuntilnoredcolorwasseen,indicatingtheabsenceofFe(III).TheformationofFe(II)-montwascon?rmedbypowderX-raydiffractionandmagneticsusceptibilitymeasurementatRTusingasuperconductingquantuminterferencedevicemagnetometer.2.3.CharacterizationofFe(II)-montmorillonite
Thetotalamountofferrousiron(andferriciron,ifany)adsorbedonthemontmorillonitewasdeterminedbyextractionwithviz.,0.05MH2SO4,1MNH4Cl,and50mMNa2EDTA.Ineachcase,aknownamount(≈0.5g)ofthesamplewasdispersedin100mlofthereagentsfor~24hunderAr.ThisextractionprocedurewasrepeatedtwicebutnotwithH2SO4topreventthepossibledissolutionofthemontmorillonite.TheFe2+/Fetotalratiowasdeterminedfromtheironreleasedin0.05MH2SO4solution,whileotherreagentsyieldedFetotal.Fe(II)-montwascharacterizedbyX-ray?uorescence(XRF,Rhtarget),powderX-raydiffraction(XRD,Cu-Kαradiation),Fouriertransforminfrared(FTIR)(KBrpellets),and57FeMössbauerspectroscopyatRTusing57Co(Rh)source.
2.4.Speci?csurfaceareabymethyleneblueandN2-adsorption
Thespeci?csurfaceareaofthesamples(Fe-1,Fe-2,Fe-1r,andFe-2r)wasdeterminedbymethyleneblue(MB)adsorption,andN2-adsorptionmethod(BET).
About0.5gofthesampleswasdispersedin100mlofwaterfor~24h.Then,MB(0.01M)wasaddeddrop-wise.Adsorptionwasmonitoredbytheso-calledspottest(Santamarinaetal.,2002).TheMBconcentrationattheendpointwasdeterminedbyaUV–Visiblespectrophotometeratλmaxof665nmafterequilibratingfor~24h.InthecaseofFe(II)-mont,theadsorptionwascarriedoutinAratmosphere.
FortheBETmeasurements,thesampleswerede-gassedatRTundervacuumformorethan24h.
2.5.StabilityofFe(II)-montmorillonite
About0.5gofthesample(Fe-1r)wasdispersedin200mlofwaterat(a)RTand(b)65°C,withArbubbling,butoccasionallyexposedtoairwhilesampling.Hencetheyaretreatedhereaspartiallydeoxygenatedconditions.About5mlofthisdispersionwasperiodicallycollectedandtreatedwith10mlof0.05MH2SO4for~24h,andthenFe2+/Fetotalratiowasdetermined.Forcomparison,Na-montwasalsotreatedsimilarlytoseeanystructuralironreleasedduetodissolution.
3.Resultsanddiscussion
3.1.Startingmaterials,Fe(III)-montmorillonite
BasedontheironextractedbyNa2EDTAsolution,Table1,totalamountofFe(III)inFe-1andFe-2wasabout2and1.25timestheCECoftheparentmontmorillonite(~113meq/100g).Theexcessironinthesesamplesispresumedtobeferric(hydr)oxidephase(Krishna-murtietal.,1998)duetotheprecipitationofFe(III)becauseofitslowsolubilityasthepHwasincreasedsuccessively(acidictoneutral)duringwashing.Also,hydrolysisandformationofoligomerse.g.,
FexOH(3y
x?y)
(KnightandSylva,1975)couldcontributetohigherFe(III)contents,butthisshouldbenegligiblysmallandthereforewasnottakenintoaccounthere.
Inthisstudy,theFe(III)-montmorillonitewasdriedatRTundervacuumbecauseairdryingwasfoundtobehighlytimeconsuming.Alternatively,itmaybeadvantageoustousefreezedrying.However,theeffectofdryingprocessontheexchangeableFe(III)ionsofthesampleneedstobeveri?ed.DuringthepreparationofFe(III)-mont,thetotalinteractiontimeofthemontmorillonitewithFeCl3solutionwas~100h.Duringthistime,partialdissolutionofthemontmor-illonitecannotberuledout.Nevertheless,theSi/Alratio(asanalyzedforelementalcompositionbyXRF)oftheclaymineral,beforeandafterthecationexchangereaction,remainedthesame(≈3.3).ToavoidthedissolutionofclaymineralinacidicreagentslikeFeCl3,weproposetotestotherFe(III)reagents(ca.ferriccomplexeshavingintermediatestabilitysothatitcandissociatetoaidcationexchangewithNa-mont)infuturestudies.
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Fig.1.WetanddriedNa-,Fe(III)-andFe(II)-mont.Upperrowphotos:freshlypreparedwetsamplesafterintensewashinginwater.Bottomrowphotos:samplesafterdryingatRT.Insets:sedimentsofdispersionusing2wt.%ofNa-andFe(III)-mont,and0.5wt.%ofFe(II)-mont.(Forcolorandclarity,thereaderisreferredtothewebversionofthis
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3.2.ConversionofFe(III)-toFe(II)-montmorillonite
ForconvertingFe(III)-toFe(II)-mont,ascorbicacid(vitaminC)wasusedasareducingagent.Thermodynamically,ascorbicacidisamildreducingagent(E0=+0.41Vvs.SHE)butcanbeakineticallystrongerreducingagentasrevealedinthereductivedissolutionofvariousFe-oxides(Manjannaetal.,2001;ManjannaandVenkateswaran,2002).Ascorbicacidishighlywatersolubleandanenvironmentallybenignreagent.DuringtheFe(III)-montreduction,slightlymorethanthestoichiometricamountofascorbicacidwasaddedtothedispersionofFe-1orFe-2underAratmosphere.Thereductionwascompletein~4hinboththesamples.Nevertheless,toachievethecompletedissolutionoftheexcessFe-oxidephase(especiallyinFe-1),thereactionwascontinuedfor~12h.ThisreactiontimecouldbeshorteneddependingontheFecontentofstartingmaterials.TheamorphousFe-oxidephaseformedatRTcanbeeasilydissolvedatthistemperature(Josephetal.,1998)unlikethesinteredoxides.Thusinthisstudythetemperaturewasraisedto~70°CtoaidthereductionofallFe(III)ions.TheconversionofFe(III)-toFe(II)-montwasvisiblyindicatedbythecolorchangefrombrowntograyishwhite,whichwassubstantiatedbymonitoringtheFe2+/Fetotalratio.TheconversionofFe(III)-toFe(II)-montmaybeshownas:2Fe(III)-mont+(H2A?2H++2e?+A)→2Fe(II)-mont+A,whereH2AandAareascorbicacidanddehydroascorbicacidrespectively.ThereleasedprotonsmayreactwithhydroxylionsofhydrolyzedFe(III)and/orferric(hydr)oxide.Thus,pHofthedispersion,justafteraddingascorbicacidandattheendofthetreatmentwas~2.5and3.7,showingtheconsumptionofH+.ItwasnotexpectedthattheprotonsreplacethestronglyadsorbedFe(II)ionsontheclaymineralsurface.InthecaseofFe-2r(Table1)theferrousionsaccountonly~86%oftheCECoftheparentclayNa-mont(113meq/100g).Undersuchsituation,H+ionscouldcompensatethemissingamountofFe(II)ions,aschargebalancingcations.ThepresenceofBrønstedacidsitesinsuchsamples(Fe-2r)mayserveasadirectevidenceforthepresenceofH+ions.Attheendofthereduction,theresidualascorbicacidwaswashedoffwithexcesswaterbycentrifugation(pHattheendwas~5.5).AsrevealedfromthereactionofFe(II)-montwithCr(VI)solution(Manjannaetal.,2006),ascorbicacidseemedtobeaweakreductanttowardsstructuraliron.Thusthereductantusedinthisstudyhadseveraladvantages.
AsstatedaboveinSection3.1,thedissolutionoftheclaymineralduringthepreparationisanimportantissue.AscheckedbyXRF,theSi/AlratioofFe-1randFe-2rwasclosetothatofthestartingmaterial
(≈3.3)indicatingthatmontmorillonitedissolutionwasnegligiblysmall.Inagreementwiththisobservation,thedissolutionrateofsmectiteatpHof3wasreportedtobeverysmall,intheorderof10?13molm?2s?1(cf.Huertasetal.,2001).Accordingtothisrate,dissolutionduringtheinteractionwithascorbicacidhereinisestimatedtobeb10?3wt.%.
InFig.1,theappearancesofstartingmaterialsandtheendproducts(i.e.,Na(I)-→Fe(III)-→Fe(II)-mont),inwetanddryforms,arecom-pared.UnlikeNa(I)-mont,Fe(III)-andFe(II)-montdonotformagelinwetcondition(upperrowphotos)becauseofrestrictedswelling(insetphotosinbottomrow).ThecolorofFe(II)-montwasgrayishwhiteinwet/beforedryingandwhitewhendriedorre-dispersedinwater.ThedegreeofswellingdecreasesintheorderNa(I)-mont?Fe(II)-montNFe(III)-mont.Suchadifferenceinswellingisanticipatedtoaffect
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Fig.2.PowderXRDpatternsofNa-,Ca-,Cr(III)-,Fe(II)-andFe(III)-mont.
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hydraulicconductivity,anddiffusion/adsorptionofradionuclidesetc.,whichareveryimportantcharacteristicsinviewoftheclaymineralalteration,Fe/clayinterface,inthegeologicaldisposalofnuclearwaste.
3.3.AdsorbedironofFe(II)-montmorillonite
TheFe2+/FetotalratioofFeextractedwith0.05MH2SO4fromfreshlypreparedsamples(Fe-1randFe-2r)wasclosetounity.Itmeansmostoftheinterlayerironisindivalentstate.Na-montreactedwith0.05MH2SO4releasedb1%ofthatinFe(II)-mont.Hencenegligiblysmallamountofclaymineraldissolutionoccurredduringthistreatment.Thus,theFe2+/FetotalratioascribedhereforinterlayerironofFe(II)-montwasnotin?uencedtoanyappreciableextentbytheclaymineraldissolution.However,long-timecontactoftheclaymineralisexpectedtoin?uencethisratio.
BasedonFetotalextractedwithNH4Cl,theCECofFe-1randFe-2rwereabout120and97meq/100g(Table1).AlmostthesameamountofFetotalwasobtainedinNa2EDTA.IftherewasanyundissolvedFe-oxidephase,FetotalinNa2EDTAwasexpectedtobehigherthaninNH4Cl.ThefactthatFetotalremainedthesameinboththereagentsindicatestheabsenceofFe-oxidephasesinthepreparedsamples.
ThedifferenceinFetotalofFe-1randFe-2rcanbeascribedtothedifferentamountsofFeinthestartingmaterials,Fe(III)-mont(Table1).TheexcessamountofadsorbedFepresentinthestartingmaterial,Fe-1,wasdissolvedcompletelyduringascorbicacidtreat-ment.Thus,additionalamountsofferrousions(probablyasferrousascorbateduetoreductivecomplexingmechanism)wereavailableinsolution.TheseFe(II)ionscanbeeasilyadsorbedontheclaymineralsurfacetocompensatethechargede?citcreatedbythereduction
Fig.3.FTIRspectraofNa-,Fe(II)-,and
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Fig.4.57FeMössbauerspectraofNa-,Fe(III)-,andFe(II)-montatRT(Fe-2andFe-2rareshownastypical
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ofinterlayerFe(III)toFe(II)ions.InthecaseofFe-2r,theCECintermsofFe(II)ionsis97meq/100gwhichis~68%ofstartingmaterial(Fe-2;CEC142meq/100g)andcorrelateswiththechargereduction,Fe3+→Fe2+.Basedonthiscorrelation,Fe-2rprobablycontainssomeprotonsascompensatingcations.Thus,aslightlyexcessamountofFe(III)inthestartingmaterial(maybeasamorphousFe-oxide)is
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Fig.5.Magneticsusceptibility(χ)ofthesolidmixtureofFe(III)-mont(Fe-2)andascorbicacid(RH≈80%)atdifferenttimeintervals.InsetisthemagnetizationoftheFe-2sampleasafunctionofapplied?eld.
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Fig.6.StabilityofFe(II)-montunderdifferent
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3.4.XRD,FTIRandMössbauerspectra
Thebasalspacing,d001,indicatingthedistancebetweentheadjacentlayersisknowntobeaffectedbythecharge,sizeandhydrationbehaviorofinterlayercations(WatanabeandSato,1998).InFig.2,thepowderXRDpatternsofFe(II)-montiscomparedwiththeNa(I)-,Ca(II)-,Fe(III)-andCr(III)-montatarelativehumidity(RH)of40%.Clearly,XRDpatternsdisplaybothbasal/symmetricre?ections(00l,whosepositionvarywithseparationbetweenlayers)andgeneralhkre?ections(twodimensional),asaconsequenceoftheturbostraticstackingoflayers.Basalspacing,d001,ofFe(II)-montdeterminedhere(14.7Å)isinagreementwiththereportedvalue(Manjannaetal.,2007),andalsowithatypicaldivalentclay,Ca(II)-mont,showninFig.2.Further,d001ofFe(II)andFe(III)-montwerefoundtobesimilarintheentireRHrange(notshownhere).Thisisprobablyduetothecompensationofionicchargevis-à-visionicradius(Fe2+is0.77ÅandFe3+is0.60Å)onthehydrationbehavior.Thesharpbasalre?ectionsintheXRDpatternalsocon?rmthecrystallinityofthesamples.
FTIRspectraofFe(II)-andFe(III)-montarecomparedwithNa(I)-montasshowninFig.3.AmongtheFe-montsamples,theplotsshownhereareforFe-1andFe-1r(?rstset),however,itwasseenthatthereisnodifferencebetweenthecorrespondingsamplesoftheotherseti.e.,Fe-2andFe-2r.Thus,allthesamplesstudiedhereshowthechar-acteristicbandsofmontmorilloniteclay,forinstance,theSi–O–Albendingvibration~520cm?1,hydroxylbendingvibrationsofAl–Mg–
OH(845cm?1)andAl2OH(918cm?1).However,thestretchingvi-brationsofSi–Ogroup~1038cm?1isslightlybroadenedinthecaseofFe-montwhencomparedtoNa(I)-mont.Thisisprobablyduetotheinteractionofinterlayer/adsorbedFewiththetetrahedralsilicatesheet.Theplausibleclaydissolutionand/orsitedistortioncannotberuledoutastheclaywasinitiallyinteractedwithacidicsolutionofFeCl3andlaterinascorbicacid,andhencethedetailedstudiesarerequired.TheFTIRspectrainthehigherenergyregion(Fig.3)areshownhereforFe(II)-,andFe(III)-mont.Thevibrationbandscorrespondingtoadsorbedwater(1630cm?1),interlayerwater(3426cm?1)andstruc-turalOHgroups(3625cm?1)haveremainedmoreorlessthesameasthatobservedfortheparentclay,Na(I)-mont.
MössbauerspectroscopyishighlysuitedforthestudyofclayswhoseindustrialusesdependontheFecontent.Nevertheless,itshouldbeviewedincombinationwithdatafromothertechniques.Fig.4showstheMössbauertransmissionspectraatRTforNa(I)-,Fe(III)-andFe(II)-mont.AmongtheFe-montsamples,Fe-2andFe-1rareshownhereasatypicalcaseofferric-andferrous-mont.MössbauerfeatureinFig.4isduetobothinterlayerandstructuraliron.Thestructuraliron(Fe2+andFe3+)ispresentintheoctahedralsheet.TherearetwositesforFewithrespecttohydroxylsintheoctahedral,cis(M2)andtrans(M1).InMössbauerspectraofsmectiteclays(Stucki,2006;Murad,1998),thecentralquadrupoledoubletatabout0.3mm/sisascribedtothestructuralFe3+andtheothersetofdoublet/scomprisingtheadditionalfeatureatabout2.2mm/sisforFe2+.InfactthereisnodetailedinformationintheliteratureabouttheinterlayerFe(andthusthedatapointsinFig.4arenot?ttedhere).ItispresumedthattheinterlayerFepresentinthecaseofFe(III)-andFe(II)-montalsogivesadditionalset/sofdoublets.AscanbeseeninFig.4,theinterlayerFe(III)wasseentoenhancethecentraldoublet/swhiletheinterlayerFe(II)wasfoundtoenhancetheadditionalfeatureatabout2.2mm/s.InthecaseofFe(III)-mont,althoughtheassociatedFe-oxidephasewaspresent,itcouldnotbedetectedatRTbecauseofitspoorly-crystallineandmagneticallynotorderedphase.Nevertheless,suchoxidephaseisexpectedtogive6-linepatternatcryogenictemperatures(Stucki,2006).
3.5.Speci?csurfaceareabymethyleneblue,andBETmethod
UV–VisiblespectraoftheMBsolution(0.01M)usedhereshowedanabsorptionmaximumat665nm,whichischaracteristicofMBmonomers.MB–claymineralinteractionisextremelysensitiveforprobingthesurfacepropertiesofsmectitesinaqueousdispersions.InthecaseofNa-mont,theadsorptioncapacitywas~10.3mol/g.Basedonanareaof130Å2permoleculeofMB(Santamarinaetal.,2002),thetotalspeci?csurfacearea(internal+external)oftheNa-montwas~810m2/g.TheamountofMBadsorbed(inmolespergramsof
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Fig.7.ColorchangesduetoairoxidationofpowderedFe(II)-mont(Fe-1r)atRTandRHb40%.A—(whitecolor):freshlypreparedsample,B—(lightbrown):50%oxidizedsample,andC—(darkbrown):completelyoxidizedsample.(Forinterpretationofthereferencestocolorinthis?gurelegend,thereaderisreferredtothewebversionofthisarticle.)
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