polymers Article Synthesis of Waterborne Polyurethane by the Telechelic α,ω-Di(hydroxy)poly(n-butyl acrylate) XinChen,ChiZhang,WeidongLi,LeiChenandWushengWang* SchoolofChemistryandChemicalEngineering,AnhuiUniversity,111JiulongRoad,Hefei230601,China; [email protected](X.C.);[email protected](C.Z.);[email protected](W.L.); [email protected](L.C.) * Correspondence:[email protected];Tel.:+86-551-6386-1279 Received:26January2018;Accepted:21February2018;Published:23February2018 Abstract: A key for the preparation of polyacrylate-based polyurethane is the synthesis of hydroxyl-terminated polyacrylate. To our knowledge, exactly one hydroxyl group of every polyacrylatechainhasnotbeenreported. Thehydroxyl-terminatedpoly(butylacrylate)(PBA)has beensuccessfullysynthesizedbydegenerativeiodinetransferpolymerization(DITP)ofthen-butyl acrylate(n-BA)using4,4(cid:48)-azobis(4-cyano-1-pentanol)(ACPO)anddiiodoxylene(DIX)asinitiator andchaintransferagent,respectively,andsubsequentlysubstitutedreactionoftheiodine-terminated PBA with β-mercaptoethanol in alkaline condition. The latter reaction was highly efficient, and the terminal iodine at the end of polymer chains were almost quantitatively transformed to a hydroxyl group. 2,2(cid:48)-Azobis(isobutyronitrile) (AIBN) and ACPO were used as initiators in the DITPs of n-BA. The results demonstrated that they had a significant influence on the terminal groups of the formed polymer chains. The structure, molecular weight, and molecular weight distributionofthehydroxyl-terminatedPBAhavebeenstudiedby1H,13CNMR,andGPCresults. Thecomponentsofhydroxyl-terminatedPBAweredeterminedbyMALDI-TOFMSspectra,andtheir formationisdiscussed. ThebroadmolecularweightdistributionofthePBAandthedifferencein thepolymerizationbehaviorsfromtypicallivingradicalpolymerizationareexplainedbasedonthe resultsof1HNMRandMALDI-TOFMSspectra. Thehydroxyl-terminatedPBAhasbeensuccessfully usedinthepreparationofPBA-basedpolyurethanedispersions(PUDs). TheaqueousPUDswere stable,andbasedontheDSCresultsitcanbesaidthatthemiscibilityofhardsegmentswithPBA chainswasimproved. Keywords: poly(n-butyl acrylate); degenerative iodine transfer; free-radical polymerization; waterbornepolyurethane 1. Introduction Polyurethanedispersions(PUDs)aregenerallysynthesizedbythecondensationpolymerization of oligomer polyols, diisocyanate, chain extender, and hydrophilic comonomers. The oligomer polyolsusedinthepreparationofPUDsaremostlydi-functionaloligomerdiols,suchaspolyether diols,polyesterdiols,andpolycarbonatediols[1]. Comparedtotheseoligomers,theadvantagesof polyacrylatearegoodadhesiontothematrices,excellentlightstability,andchemicalresistance. PUDs arewell-knownfortheirpeculiaradvantages,suchashighimpactstrengthatlowtemperatures,tear resistance,andgoodelasticity[2–5]. Ifpolyurethaneandpolyacrylatearecombinedinonepolymerto formpolyacrylatepolyurethane,thenewlyformedPUDsmayhavetheadvantagesofbothpolymers, which may have potential applications [6–8]. At present, the commercially available polyacrylate polyolshavebeenmanufacturedbythecopolymerizationofacrylatemonomersandhydroxy-alkyl acrylatemonomers(e.g.,2-hydroxyethylacrylate),andthehydroxylgroupsarerandomlydistributed inthepolymersidechains. Ingeneral,thehydroxylcontentis2–4%,andtheaveragefunctionalityis Polymers2018,10,219;doi:10.3390/polym10020219 www.mdpi.com/journal/polymers Polymers2018,10,219 2of16 greaterthanthree[9–11]. Becausethestructureandfunctionalityofthepolyacrylatepolyolchains are inhomogeneous, and cross-linking reaction may occur when this kind of polyol reacts with isocyanate,polyacrylatepolyolsareseldomusedtoprepareaqueousPUDs. Althoughpreparationof thewaterbornepolyurethane–polyacrylatehybridemulsionshasbeenreported,lowcompatibility between the polyurethane and the polyacrylate has limited its applications [12–16]. This problem can be solved by using the polyacrylate as soft segments of aqueous PUDs. The key issue for achievingthispurposeisthesynthesisoftheoligomerpolyacrylatediol. However,severalreview papersmerelydiscussthesynthesisofthepolyacrylatediols[17,18];onlyoneU.S.patentwewere abletofindintheliteratureinvolvedthesynthesisofhydroxyl-terminatedpolyacrylates[18]. Itis difficulttobelievethatbothendsofeverypolymerchainarecappedwithahydroxylgroupbecause 2,2(cid:48)-azobis(isobutyronitrile)(AIBN)isusedinthepreparation,whichwillbediscussedfurther. Livingradicalpolymerization(LRP)hasbeenshowntobeaviablemethodfortherationaldesign ofpolymerswithpredictablemolecularstructureandnarrowmolecularweightdistributions[19,20], andfundamentalkineticfeaturesoftheLRPhasbeendiscussed[19,20]. Amongseveralstrategiesof LRPs,degenerativeiodinetransferpolymerization(DITP)hasbeenreceivingourspecialattention becausetheiodinegroupattheendoftheformedpolymercanbealmostquantitativelytransformed to a hydroxyl group via a simple procedure. However, other LRPs (e.g., atom transfer radical polymerization and reversible addition-fragmentation chain transfer polymerization) can also be used in the preparation of polyacrylate diols. DITP controls chain growth through a reversible reactionofthegrowingchainradicalswithiodocompound,limitingirreversibleterminationofthe growingchainradicals;themechanismofDITPandDITPinthepresenceofhalogenatedmonomers have been discussed in detail [21]. A number of homopolymers and block copolymers including polystyrene (PS), poly(methyl methacrylate) (PMMA), and poly(vinyl chloride) (PVC) have been successfully synthesized through DITP [20,22–26]. In the case of solution polymerization, a large varietyofsolvents(e.g.,toluene,anisole,etc.) canbeusedaspolymerizationmedia[20,22]. DITPhas beensuccessfullyusedinemulsionpolymerizationforthepreparationofpolystyrene-b-poly(butyl acrylate) [20,22,27]. Many studies have demonstrated that the DITP is a feasible method for the synthesis of low-molecular-weight polyacrylate (M = 2000–6000 g mol−1), but the ratio of n iodine-end-cappedfunctionalgroupscannotreach100%(mostlyonly50–80%). Besidestheiodine,the otherendgroupcomesfromtheinitiatorfragment[28,29]. Conversionoftheend-iodinegroupsinto hydroxylgrouphasbeenstudied[18,30],buttheyieldedproductcannotbeusedinsynthesisofhigh molecularweightpolyurethane. Thepurposeofthestudyreportedhereinistosynthesizeawell-definedα,ω-di(hydroxy)poly(n- butylacrylate)withrelativelylowmolecularweight,andthentouseitinthesynthesisofPUDswith polyacrylateassoftsegment. 2. MaterialsandMethods 2.1. Materials 4,4(cid:48)-Azobis(4-cyano-1-pentanol)(ACPO)waspurchasedfromHenanLienchemInc. (Zhengzhou China). 2,2(cid:48)-Azobis(isobutyronitrile)(AIBN)wasboughtfromEnergyChemical(Shanghai,China) andpurifiedbyrecrystallizationinethanol. n-Butylacrylate(n-BA),α,α(cid:48)-dibromo-p-xylene,decane, d-chloroform(CDCl ),andisophoronediisocyanate(IPDI)werepurchasedfromMacklin(Shanghai, 3 China). Toluene, 2-mercaptoethanol, 2,2-dimethylol propionic acid (DMPA), and acetone were purchasedfromSinopharmChemicalReagentCo.,Ltd. (Shanghai,China). Calciumoxide,potassium carbonate(K CO ),1,4-butanediol,andtriethylaminewereboughtfromAladdin(Shanghai,China). 2 3 Allotherchemicalswereusedasreceived. Polymers2018,10,219 3of16 2.2. Methods 1H nuclear magnetic resonance (1H NMR) and 13C nuclear magnetic resonance (13C NMR) (400MHz)wereperformedatroomtemperatureonAVANCEII400MHzspectrometersinCDCl 3 usingtetramethylsilaneasaninternalstandard. Molecular weight and molecular weight distribution were measured on a PL-GPC120 gel permeationchromatograph(GPC)equippedwithaPLGel5µmcolumn(300×7.5mmpurchasedfrom PolymerLaboratories(SantaClara,CA,USA))andarefractiveindexdetector(G1362A1100/1200series refractiveindexdetector(AgilentTechnologiesInc.,SantaClara,CA,USA)at40◦C.Tetrahydrofuran (THF)wasusedassolventataflowrateof1mL/min. Themonodispersepolystyrenestandards(test rangeofmolecularweightswasfrom1000to200,000g/mol,PolymerLaboratories)wereutilizedin thecalibrationofM ,M ,andM /M . Sampleconcentrationwas1mg/mL,andsampleinjection n w w n volumewas300µL. Mass-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF) measurements were performed on a Bruker Autoflex III TOF/TOF mass spectrometer (Bruker Daltonics Inc., Billerica, MA, USA). The instrument was operated in positive ion reflection mode withanacceleratingpotentialof+20kV.trans-2-[3-(4-tert-butylphenyl)-2-methyl-2-proprnylidene] malononitrilewasusedasamatrixanddichloromethaneasasolvent. Sodiumiodidewasdissolvedin methanolandusedastheionizingagent. Sampleswerepreparedbymixing2µLofpolymersolution with2µLofmatrixsolution. Then,1.0µLofthesemixtureswasdepositedonatargetplateandthe solventwasremovedinastreamofnitrogen. The hydroxyl number of the α,ω-di(hydroxy)poly(n-butyl acrylate) was determined by the phthalicanhydriderefluxmethodinaccordancewithASTMStandardD2849. Differentialscanningcalorimetry(DSC)analysiswasconductedonaQ2000ofTAinstruments (TA Instruments, New Castle, DE, USA) in the range of −80 ◦C to 150 ◦C. The experiments were carriedataheatingrateof20◦C/minundernitrogenflowatarateof20mL/min. Thesampleswere driedat65◦Cfor48hundervacuumpriortoanalysis. Thestabilityofemulsionswascharacterizedbycentrifugationat3000rpm/minfor15minat roomtemperature,andthenwereobservedtoevaluatewhetherprecipitationoccurred. Particlesizeandparticlesizedistributionweremeasuredat25◦CwithZetasizerNanoseriesZS 90(MalvernInstrumentsLtd.,Malvern,UK).Thesamplesweredilutedto1.85%(massconcentration) indistilledwater. 2.3. SynthesisofDiiodoxylene Thesyntheticprocedurewassimilartothepreviousreport[23,31]. Sodiumiodide(0.08mol)and α,α(cid:48)-dibromo-p-xylene(0.03mol)weredissolvedinacetoneundernitrogen. Thereactionwascarried outatroomtemperature,andaftersubsidence,thestirringwascontinuedforanadditional30min. Theproductwasprecipitatedbyaddingwater(250mL),andthesaltformedwasdissolvedinwater. Then,theprecipitatewasremovedbyfiltration,washedwithwaterfivetimes,andthefinalproduct wasobtainedbydryinginavacuumovenatroomtemperatureovernight. 2.4. DegenerativeIodineTransferPolymerizationofn-BA n-BA(0.39mol),ACPO(0.02mol),diiodoxylene(0.04mol),andtoluene(120mL)wereplacedin a500mLround-bottomflaskprotectedinthedark. Thereactionmixturewasheatedinanitrogen atmosphereat60◦Cundermagneticstirring. After24h,thepolymerizationsolutionwascooledin anicebath. Subsequently,potassiumcarbonate(K CO )wasaddedintotheflaskinordertochange 2 3 thepHofthereactionmixturetoalkalinity,andthenβ-mercaptoethanolwasaddedtothereaction mixturefortransformationofend-iodinetoend-hydroxylgroup. Thereactionsolutionwascollected byfiltrationthrough1.0µmmicroporousfilters,andtolueneinthecollectedsolutionwasremovedby rotaryevaporation. Then,thetargetproductwaspurifiedbywashingwithethanolanddistilledwater. Polymers2018,10,219 4of16 Aftertheethanolintheproductwasremovedinavacuumoven,asampledissolvedintoluenewas heatedat110◦Cfortheremovalofwaterandthepurifiedproductwasobtained. 2.5. KineticsStudyofPoly(n-butylacrylate)byDegenerativeIodineTransferPolymerization In order to study the kinetic features of this bulk polymerization system, we carried out the polymerizationsat60◦Candtooksamplesperiodicallyatthedesignedpolymerizationtime(24h). Monomerconversionwasdeterminedbygravimetricanalysis. Severaldropsof4-hydroxyanisole (MEHQ)(0.5wt%)wereaddedto0.5mLofpolymersolutionevery30min. Then, weplacedthe sampleinanicebath. Thesmallmoleculesinsolutionwerethenremovedbyvacuumdryingat65◦C. Theweightbeforeandafterdryingwascompared,andmonomerconversionwasobtainedbythe equation: m Conversion(%) = 3 ×100% m − m 1 2 wherem istheweightofsolution,m istheweightofsolvent,andm istheweightofdriedpolymer. 1 2 3 Theobtainedpolymerwascharacterizedby1HNMRspectroscopy. 2.6. SynthesisofPolyacrylate-BasedPolyurethaneDispersions(PUDs) Poly(n-butylacrylate)diol(6.67 × 10−3 mol)waschargedunderstirring, andtheisophorone diisocyanate(IPDI)(0.03mol)wasthenslowlyaddedintothediol. Themixturewasthenheatedto 80–85◦Cuntilthetheoreticalisocyanategroup(NCO)contentoftheprepolymerwasreached,which wasestimatedusingthedi-n-butylaminetitrationmethod. Then,thechainextenders1,4-butanediol anddimethylolpropionicacid(DMPA)(9.40×10−3 mol)wereaddedintothemixtureatthesame temperaturefor1.0hthroughadjustingtheviscositybyacetone. Distilledwater(106mL)wasthen addedintotheneutralizedPUbyusingtriethylamine(9.4×10−3mol)asaneutralizingagentafter addingcatalyst. Anaqueousdispersionof20wt%solidswasobtainedafterremovalofacetoneby decompressingdistillation. 3. ResultsandDiscussion 3.1. DesignofDITPSystemforPreparationofHydroxyl-TerminatedPoly(butylacrylate) Topreparelow-molecular-weightpoly(butylacrylate)(PBA)withbothendscappedwithhydroxyl groupsviaDITP,thefirstissueisthedesignofanappropriatepolymerizationsystem. Accordingto previousreports[18,32],hydroxyl-terminatedpolyacrylatecouldbepreparedbytheDITPofacrylates usingdiiodoxylene(DIX)andAIBNasdi-functionalchaintransferagentandinitiator,respectively, andthispatentclaimedthattheend-functionalizedpolymerswereusefulasreactiveintermediatesin condensationpolymerization,chainpolymerization,andheterogeneouspolymerization. Therefore, wefirstpreparedthePBAdiolsaccordingtothereportedmethod[18]. TheresultsarelistedinTable1, andthemolecularweightwasdeterminedbyGPC,theOHvaluewasmeasuredbyphthalicanhydride refluxmethod,andthefunctionalityofend-hydroxylgroupwascalculatedbasedon1HNMRspectra asshowninFigure1. Surprisingly,weobservedthatthefunctionalityofend-hydroxylgroupinthe resultant polymers was less than 60% (Table 1). Thus, it is necessary to clarify what happened in thispolymerization. Polymers2018,10,219 5of16 Polymers 2018, 10, x FOR PEER REVIEW 6 of 15 Figure 1a,b show the proton NMR spectra of the PBA obtained respectively from DITP for 1 h Table1.Degenerativeiodinetransferpolymerization(DITP)conditionandresultsofn-butylacrylate and c(no-mBAp)leutes icnogndvieiorsdiooxny olefn ne-B(DAI.X T)haen dpr2o,2to(cid:48)-na zsoigbinsa(ilsso abtu tδy =ro 4n.i0tr4i,l e2).3(6A, IaBnNd) 1a.s91tr panpsmfe raraeg ernestpaencdtively ascribineidtia ttoo rt,hrees epsetcetriv melye.thylene group and the methine and methylene groups in the backbone of the PBA chain; the aromatic protons and two methylene protons of the xylene units appear at δ = 7.05 and 2.51 ppm, respectively. Other proton signals oMf the PBA arOe Hmavraklueed in FigFuurnec t1io, naanldit ythoef vinyl signaElxsp o.f* n-BA[n -mBAo]n:[oAmIBeNr a]:t[ C6T.3A8s, ]6.C14o,n av.n(d% 5).83 pp(gmmn c,oGolP−mC1p)lete(lmy gdiKsaOpHp/ega)r in eFnidg-uhryed 1robx; yall(l% o)f athese results 1indicate tha1t 0P:1B:0A.5 was successfu8l9ly synthesiz2e3d1.0 The signal o15f methylene proto4n2s in the DIX unit at 2δ = 4.45 ppm1 a0l:1m:1ost disappeare8d7, and a new2 s0i2g0nal at δ = 4.3200 ppm appeared i4n0 Figure 1a,b, 3 10:0.5:1 83 1910 25 54 which is attributed to the methine proton of the BA unit next to terminal iodine. This demonstrates 4 10:0.24:1 78 1680 26 49 that reversible transfer reaction of the growing chain radical with DIX occurred, forming p- 5 10:0.16:1 76 1540 28 48 iodomethylene benzyl radicals and then initiating n-BA to polymerize, producing PBA. Based on the *Allofthereactiontimeswere7.5haccordingthereport[18].aCalculatedby([ICH2/2]/([ICH3/6]+[ICH2/2])× integ1r0a0t,iwonhe rreatIiCoH 3oifs tthheei nsiteggnraall vaatl u4e.3o0f mpeptmhy lapnrodt otnhoef stihgeninailt iaatto 4r.f4ra5g pmpenmt,a ta1p.2p0r–o1.x3i0mpapmte,lyan 9d0I%CH 2oifs tthhee DIX unitsi nwteegrrael lvoacluaeteodfm inet hthylee nmepidrodtolen sooff PβB-mAer ccahpatoinetsh.a nolat3.6–3.8ppm. Figure 1. 1H NMR spectra of the polymers respectively obtained from (a) the DITP of n-BA using Figure1. 1HNMRspectraofthepolymersrespectivelyobtainedfrom(a)theDITPofn-BAusing AIBN as initiator and DIX as transfer agent for 1 h, and (b) for complete consumption of BA. (c) The AIBNasinitiatorandDIXastransferagentfor1h,and(b)forcompleteconsumptionofBA.(c)The polymer obtained after converting the iodide group at the ends of the polymer in (b) into the hydroxyl polymerobtainedafterconvertingtheiodidegroupattheendsofthepolymerin(b)intothehydroxyl group through reaction with β-mercaptoethanol. groupthroughreactionwithβ-mercaptoethanol. When the iodine-terminated PBA was treated with β-mercaptoethanol, the hydroxyl-terminated BasedonthemechanismofDITPreportedinReferences[21,24],theDIPTmechanismofBAcan PBA was obtained, and its proton NMR spectrum is shown in Figure 1c. We can see that the proton bedepictedinScheme1. Thechaingrowthiscontrolledbyreversiblereactionofthegrowingchain signals at δ = 4.45 and 4.30 ppm completely disappeared, two new proton signals appeared in Figure radicalswithDIX,andafterthepolymerization,thexylenegroupsarelocatedinthemiddleofPBA 1c: one signal at δ = 3.73 ppm, which is ascribed to methylene protons next to the terminal hydroxyl chain;however,thePBAwithoutxylenegroupcannotbeexcluded. Accordingtothismechanism, group; another at δ = 2.67–2.96 ppm, which is attributed to methylene protons adjacent to an ether thechainendgroups—whichareofespecialinterestinthisstudy—includeiodineandisobutyronitrile sulfur atom. These results demonstrate that the substitute reaction of HOCH2CH2SK with PBA-I is groups. Whentheβ-mercaptoethanolwasaddedintothereactionsystem,theiodineattheendof almost quantitative. When we carefully analyze the 1H NMR spectrum in Figure 1c, we can observe a proton signal at δ = 1.26 ppm, which is ascribed to methyl protons of the isobutyrontrile unit. Based Polymers 2018, 10, x FOR PEER REVIEW 5 of 15 Based on the mechanism of DITP reported in References [21,24], the DIPT mechanism of BA can be depicted in Scheme 1. The chain growth is controlled by reversible reaction of the growing chain radicals with DIX, and after the polymerization, the xylene groups are located in the middle of PBA chain; however, the PBA without xylene group cannot be excluded. According to this mechanism, tPholey mecrhsa20in18 ,1e0n,d21 9groups—which are of especial interest in this study—include iodine 6aofn1d6 isobutyronitrile groups. When the β-mercaptoethanol was added into the reaction system, the iodine at the end of the formed polymer chains could be converted to a hydroxyl group. In order to verify theformedpolymerchainscouldbeconvertedtoahydroxylgroup. Inordertoverifytheseresults, these results, 1H NMR was used to follow the polymerization, and typical 1H NMR spectra are shown 1HNMRwasusedtofollowthepolymerization,andtypical1HNMRspectraareshowninFigure1. in Figure 1. initation: CN CN CN H3C C N N C CH3 2H3C C +N2 CH3 CH3 CH3 chainpropagation: CN CN CH3 C +H2C CH H3C C CH2 CH CH3 COOBu CH3 COOBu CHNH H CN H3C C CH2 C +nH2C CH H3C C CH2 CH CH3 COOBu COOBu CH3 COOBu chaintransfer: CN CH2NH2 2 H3C C CH2 CH + I CH2 CH2 I 2H3C C CH2 CH I + CH3 COOBu CH3 COOBu chainpropagation: H H +2H2C CH C CH2 CH2 CH2 CH2 C COOBu CH2OOBu CH2OOBu H H C CH2 CH2 CH2 CH2 C +nH2C CH COOBu COOBu COOBu degenerativechaintransfer: H H CN CN H H C CH2CH2 CH2 CH2 C +2H3C C CH2CH I 2H3C C CH2CH + I C CH2 CH2 CH2 CH2 C I COOBu COOBu CH3 COOBu CH3 COOBu COOBu COOBu CN CN + 2H3C C CH2CH I 2H3C C CH2CH + I I CH3 COOBu CH3 COOBu termination: CN CN CN H 2H3C C CH2 CH + H3C C CH2 C CH CH2 C CH3 CH3 COOBu CH3 COOBu COOBu CH3 CN CN CN 2H3C C CH2 CH H3C C CH2 CH CH CH2 C CH3 CH3 COOBu CH3 COOBuCOOBu CH3 OH HS I I HO OH K2CO3 Scheme1.Mechanismofthedegenerativeiodinetransferpolymerizationofn-BA. Scheme 1. Mechanism of the degenerative iodine transfer polymerization of n-BA. Figure1a,bshowtheproton NMRspectraofthePBAobtainedrespectivelyfromDITPfor1h andcompleteconversionofn-BA.Theprotonsignalsatδ=4.04,2.36,and1.91ppmarerespectively ascribedtotheestermethylenegroupandthemethineandmethylenegroupsinthebackboneofthe PBAchain;thearomaticprotonsandtwomethyleneprotonsofthexyleneunitsappearatδ=7.05 and2.51ppm,respectively. OtherprotonsignalsofthePBAaremarkedinFigure1,andthevinyl signalsofn-BAmonomerat6.38,6.14,and5.83ppmcompletelydisappearinFigure1b;allofthese resultsindicatethatPBAwassuccessfullysynthesized. ThesignalofmethyleneprotonsintheDIX Polymers2018,10,219 7of16 unitatδ=4.45ppmalmostdisappeared,andanewsignalatδ=4.30ppmappearedinFigure1a,b, whichisattributedtothemethineprotonoftheBAunitnexttoterminaliodine.Thisdemonstratesthat reversibletransferreactionofthegrowingchainradicalwithDIXoccurred,formingp-iodomethylene benzylradicalsandtheninitiatingn-BAtopolymerize,producingPBA.Basedontheintegrationratio ofthesignalat4.30ppmandthesignalat4.45ppm,approximately90%oftheDIXunitswerelocated inthemiddleofPBAchains. Whentheiodine-terminatedPBAwastreatedwithβ-mercaptoethanol,thehydroxyl-terminated PBAwasobtained,anditsprotonNMRspectrumisshowninFigure1c. Wecanseethattheproton signalsatδ=4.45and4.30ppmcompletelydisappeared,twonewprotonsignalsappearedinFigure1c: one signal at δ = 3.73 ppm, which is ascribed to methylene protons next to the terminal hydroxyl group;anotheratδ=2.67–2.96ppm,whichisattributedtomethyleneprotonsadjacenttoanether sulfuratom. TheseresultsdemonstratethatthesubstitutereactionofHOCH CH SKwithPBA-Iis 2 2 almostquantitative. Whenwecarefullyanalyzethe1HNMRspectruminFigure1c,wecanobservea protonsignalatδ=1.26ppm,whichisascribedtomethylprotonsoftheisobutyrontrileunit. Basedon thepolymerizationmechanismshowninScheme1,thisinitiatorfragmentshouldstandattheend ofthePBAchain. Therefore,theobtainedPBAhastwoendgroups: hydroxylandisobutyrontrile. The hydroxyl functionality of the obtained PBA can be calculated based on integral values of the signalsatδ=1.26and3.73ppm,andtheresultsarelistedinTable1. Theoretically,therearethree typesofPBAbasedontheirdifferentendgroups,HO–PBA–OH,HO–PBA–I,andI–PBA–I(Irefersto isobutyrontrilegroup). TheresultsinTable1showthatthehydroxylfunctionalityofallobtainedPBAs isapproximately50%;themolarpercentageofHO–PBA–OH—whichisexpectedinthepreparationof aqueousPUDs—waslessthan50%. Suchhydroxyl-functionalizedPBAwillsignificantlyinfluencethe propertiesoftheformedaqueousPUDsbecausetheI–PBA–Iisinertinthereactionwithdiisocynates andtheHO–PBA–Iterminatesthecondensationpolymerizationofdiolwithdiisocynatemonomers. TosynthesizethePBAwith100%hydroxylfunctionality,thedesignofanewformulationisnecessary. Basedontheabovediscussion,thelowhydroxylfunctionalityofthePBAisduetotheuseofAIBN withouthydroxylgroupasinitiator;thus,theinitiatorACPOwithtwoterminalhydroxylgroupswas selectedandusedintheDITPofn-BA. 3.2. DITPofn-BAUsingDIXandACPOasTransferAgentandInitiator Inordertosynthesizelow-molecular-weightPBAwith100%hydroxylfunctionalityforapplication inthepreparationofaqueousPUDs,lowfeedmolarratioofmonomertotransferagentisgenerally required. Thus, the DITP of n-BA with feed molar ratio of [n-BA]/[ACPO]/[DIX] = 16:0.08:1 was conductedat60◦Cfor24h. ThePBAwasobtainedbyprecipitation,filtration,anddrying,anditsGPC curveand1HNMRspectrumweremeasured. Figure2showsitsGPCcurve,whichrevealsasingle curvewithapronouncedtail. Theprobablereasonisirreversibleterminationofthegrowingchain radicals,becauseattheinitialstageofpolymerization,fastdecompositionofinitiatorACPOproduced toomanyprimaryradicals,andthenthegrowingchainradicalscouldnotbeefficientlycapturedby transferagent(DIX),leadingtotheirirreversibletermination. ThetailoftheGPCcurveledtoabroad molecularweightdistribution(M /M =1.67). w n After the iodine-terminated PBA was treated with β-mercaptoethanol in alkaline conditions, thehydroxyl-terminatedPBAwasobtained,andits1HNMRspectrumwasmeasuredandisshownin Figure3. Similartothe1HNMRspectrumofPBAobtainedbyinitiationofAIBN,thecharacteristic ester methylene proton signal, the methane, and methylene proton signals in the PBA backbone appearatδ=4.08,2.33,and1.96ppm,respectively,demonstratingthesuccessfulsynthesisofPBA. TheiodomethyleneprotonsignalofDIXunitatδ=4.45ppmcompletelydisappeared, andanew protonsignalclearlyappearedatδ=2.57ppm. Thisisbecausethereversiblereactionofthegrowing PBAchainradicalswithDIXproducedp-iodomethylenebenzylradicalsandtheiodine-terminated PBA,andtheformalradicalsinitiatedthepolymerizationofn-BAtoformPhCH –n-BAlinkage. So, 2 themethyleneprotonsignaloftheDIXwasshiftedfromδ=4.45to2.57ppm. Asinthediscussion Polymers 2018, 10, x FOR PEER REVIEW 7 of 15 on the polymerization mechanism shown in Scheme 1, this initiator fragment should stand at the end of the PBA chain. Therefore, the obtained PBA has two end groups: hydroxyl and isobutyrontrile. The hydroxyl functionality of the obtained PBA can be calculated based on integral values of the signals at δ = 1.26 and 3.73 ppm, and the results are listed in Table 1. Theoretically, there are three types of PBA based on their different end groups, HO–PBA–OH, HO–PBA–I, and I–PBA–I (I refers to isobutyrontrile group). The results in Table 1 show that the hydroxyl functionality of all obtained PBAs is approximately 50%; the molar percentage of HO–PBA–OH—which is expected in the preparation of aqueous PUDs—was less than 50%. Such hydroxyl-functionalized PBA will significantly influence the properties of the formed aqueous PUDs because the I–PBA–I is inert in the reaction with diisocynates and the HO–PBA–I terminates the condensation polymerization of diol with diisocynate monomers. To synthesize the PBA with 100% hydroxyl functionality, the design of a new formulation is necessary. Based on the above discussion, the low hydroxyl functionality of the PBA is due to the use of AIBN without hydroxyl group as initiator; thus, the initiator ACPO with two terPmolyinmaerls h2y01d8r,o10x,y2l1 9groups was selected and used in the DITP of n-BA. 8of16 3.2. DITP of n-BA Using DIX and ACPO as Transfer Agent and Initiator ofthe1HNMRspectrainFigure1, theendgroupsofPBAcomefrominitiatorandtransferagent. ThIent eormrdienra ltoio dsiynnethoefsPizBeA –loIwch-mainolsewcualsarc-owneviegrhtte dPtBoAa hwyidthro x1y00l%gr ohuypdbroyxryela cftuionnctoiofnPaBliAty– Ifwori th apHplOic–aCtioHn CinH thSeK p,rwephaircahtiiosnc oofn fiaqrmueeodusb yPUitDs 1sH, loNwM feRedsp mecotlraurm raitnio Foifg muroen3o.mTehre tos itgrnaanlsfoefr mageethnitn e 2 2 is pgreonteornalilny threeqtueirrmedin. aTlhnu-Bs,A thuen iDtaItTδP =o4f .3n0-BpAp mwcitohm fpeleedte mlyodlaisra prapteioa reodf ,[ann-BdAtw]/[oApCrPotOo]n/[sDigIXna] l=s at 16:δ0.=082:.16 7waansd c3o.n62d–u3c.9te3dp aptm 60a p°pCe aforerd 2i4n hF.i gTuhree 3P,BwAh iwchasa roebrteasinpeedct ibvye lypraetctripibiutatteidonto, ftiwltroamtioenth, yalnedne s, dryreinspge, catnivde liyts aGdPjaCc ecnutrvtoe saunldfu 1rHa nNdMhRy dspoexcytlrugmro uwpesr.e Tmheeaspurroetdo.n Fsiiggunrael 2o fshthowe ste irtms GinPaCl h cyudrrvoex, yl whgircohu rpe,vweahlisc ha scionmglees cfurorvme twheithA Ca PpOroninoiutinatcoerd, atalsiol. aTphpe eparrosbaatbδle= r3e.a6s2o–n3 .i9s3 irprpevme.rsBiebclea utesremthineaptiroonto n of nthuem gbreorwoifntgh echtwaion mraedthicyallesn, ebeacnadutshee apt hthene yinleintieali nsttahgeeD oIfX pioslythmeesraimzaeti,othne, fcaosnt tdriebcuotmiopnorsaittiioono fotfh e iniitniaittioart oArCAPCOP Opraondducteradn tsofoer magaennyt pDrIimXatoryt hreadteicramlsi,n aanldh ytdhreonx tyhleg grorouwpicnagn cbheaeinst rimadaitceadlsb caosuelddo nnotth e bei neftfeigcireantitolyn craaptitouorefdth beys itgrannaslfseart aδg=en3t. 6(D2–I3X.)9,3 leaanddin7g.0 t4op tphmeir, airnrdeviser0s.i0b7l/e 1t—ermcloinsaettioont.h Tehfeee tdaiml oofl ar ther aGtiPoCo fcu[ArvCeP lOed]/ t[oD aI Xb]ro=a0d. 0m8/o1le.cular weight distribution (Mw/Mn = 1.67). Polymers 2018, 10, x FOR PEER REVIEW 8 of 15 CH2CH2SK, which is confirmed by its 1H NMR spectrum in Figure 3. The signal of methine proton in the terminal n-BA unit at δ = 4.30 ppm completely disappeared, and two proton signals at δ = 2.67 and 3.62–3.93 ppm appeared in Figure 3, which are respectively attributed to two methylenes, respectively adjacent to sulfur and hydoxyl groups. The proton signal of the terminal hydroxyl group, which comes from the ACPO initiator, also appears at δ = 3.62–3.93 ppm. Because the proton number of the two methylene and the phenylene in the DIX is the same, the contribution ratio of the initiator ACFPigOFui greau n2red. G2 .terlGa penelsrpfmeerer amatiegoaentni cothn rDochmIXrao tmotoga rtaothpghera ypt (ehGrymP(CGin)P caCul r)hvceyusdr vorfeo stxhoyefl p thogelryopmuoeplyr mocbaetnra ionbbeetda iefnrseotdmimf trahoteme Ddt IhTbePaD soeIfT dnP -oonf the intBegAnr wa-BtiiAtohnw f erietahdt ifmoee oodlfam rt hroaelat isroirsga ontifao [lsnso- BaftA[ nδ]-/ B[=AA 3C]./P6[2OA–]C3/DP.9IO3X] ]/a =nD 1dI6X /7]0.=.00481 /6p1/ p(0Mm.0n8,, G/aP1Cn (d=M 3i2s0 00. 0g7/=m/13o—2l0).0c lgo/sme otol) .the feed molar n,GPC ratio of [ACPO]/[DIX] = 0.08/1. After the iodine-terminated PBA was treated with β-mercaptoethanol in alkaline conditions, the hydroxyl-terminated PBA was obtained, and its 1H NMR spectrum was measured and is shown in Figure 3. Similar to the 1H NMR spectrum of PBA obtained by initiation of AIBN, the characteristic ester methylene proton signal, the methane, and methylene proton signals in the PBA backbone appear at δ = 4.08, 2.33, and 1.96 ppm, respectively, demonstrating the successful synthesis of PBA. The iodomethylene proton signal of DIX unit at δ = 4.45 ppm completely disappeared, and a new proton signal clearly appeared at δ = 2.57 ppm. This is because the reversible reaction of the growing PBA chain radicals with DIX produced p-iodomethylene benzyl radicals and the iodine-terminated PBA, and the formal radicals initiated the polymerization of n-BA to form PhCH2–n-BA linkage. So, the methylene proton signal of the DIX was shifted from δ = 4.45 to 2.57 ppm. As in the discussion of the 1H NMR spectra in Figure 1, the end groups of PBA come from initiator and transfer agent. The terminal iodine of PBA–I chains was converted to a hydroxyl group by reaction of PBA–I with HO– FFiigguurree 33.. 11HH NNMMRR ssppeeccttrruumm ooff tthhee ppoollyy((bbuuttyyll aaccrryyllaattee)) ((PPBBAA)) ssyynntthheessiizzeedd bbyy DDIITTPP ooff tthhee nn--BBAA wwiitthh ffeeeedd mmoollaarr rraattiiooo off[ n[n-B-BAA]/]/[[AACCPPOO]]//[[DDIIXX]] == 1166//00..0088//11 aatt 6600 °◦CC ffoorr 2244 hh ((MMn,GPC == 33220000 gg//mmooll)). .AACCPPOO:: n,GPC 44,,44′(cid:48)--aazzoobbiiss((44--ccyyaannoo--11--ppeennttaannooll)).. The 13C NMR spectrum in Figure 4 supports the structure of hydroxyl-terminated PBA, which The 13C NMR spectrum in Figure 4 supports the structure of hydroxyl-terminated PBA, was obtained based on analysis of its 1H NMR spectrum in Figure 3; the signal of the terminal whichwasobtainedbasedonanalysisofits1HNMRspectruminFigure3;thesignaloftheterminal hydroxylmethylene carbon appears at δ = 64.29 ppm, and the ascription of the other carbon signals hydroxylmethylenecarbonappearsatδ=64.29ppm,andtheascriptionoftheothercarbonsignalsin in the hydroxyl-terminated PBA are marked in Figure 4. thehydroxyl-terminatedPBAaremarkedinFigure4. Figure 4. 13C NMR spectrum of the PBA synthesized by DITP of the n-BA with feed molar ratio of [n- BA]/[ACPO]/[DIX] = 16/0.08/1 at 60 °C for 24 h (Mn,GPC = 3200 g/mol). Polymers 2018, 10, x FOR PEER REVIEW 8 of 15 CH2CH2SK, which is confirmed by its 1H NMR spectrum in Figure 3. The signal of methine proton in the terminal n-BA unit at δ = 4.30 ppm completely disappeared, and two proton signals at δ = 2.67 and 3.62–3.93 ppm appeared in Figure 3, which are respectively attributed to two methylenes, respectively adjacent to sulfur and hydoxyl groups. The proton signal of the terminal hydroxyl group, which comes from the ACPO initiator, also appears at δ = 3.62–3.93 ppm. Because the proton number of the two methylene and the phenylene in the DIX is the same, the contribution ratio of the initiator ACPO and transfer agent DIX to the terminal hydroxyl group can be estimated based on the integration ratio of the signals at δ = 3.62–3.93 and 7.04 ppm, and is 0.07/1—close to the feed molar ratio of [ACPO]/[DIX] = 0.08/1. Figure 3. 1H NMR spectrum of the poly(butyl acrylate) (PBA) synthesized by DITP of the n-BA with feed molar ratio of [n-BA]/[ACPO]/[DIX] = 16/0.08/1 at 60 °C for 24 h (Mn,GPC = 3200 g/mol). ACPO: 4,4′-azobis(4-cyano-1-pentanol). The 13C NMR spectrum in Figure 4 supports the structure of hydroxyl-terminated PBA, which was obtained based on analysis of its 1H NMR spectrum in Figure 3; the signal of the terminal hydroxylmethylene carbon appears at δ = 64.29 ppm, and the ascription of the other carbon signals Polymers2018,10,219 9of16 in the hydroxyl-terminated PBA are marked in Figure 4. FigFuigreu r4e. 143.C1 N3CMNRM spRecstpreucmtr uomf thoef PthBeAP sByAntshyensitzheedsi bzeyd DbITyPD oITf tPhoe fnt-hBeAn w-BitAh wfeietdh mfeoeldarm roatliaor oraf t[ino-of BA[n]/-[BAAC]P/O[A]/C[DPOIX]]/ =[D 1I6X/0].=081/16 /a0t .6008 /°1C afto6r 024◦ Ch f(oMrn2,G4PCh =( M3200 g/m=o3l2)0. 0g/mol). Polymers 2018, 10, x FOR PEER REVIEW n,GPC 9 of 15 TToo ffuurrtthheerr vveerriiffyy tthhee ssttrruuccttuurree aanndd tthhee tteerrmmiinnaall ggrroouuppss ooff PPBBAA,, iittss MMAALLDDII--TTOOFF mmaassss ssppeeccttrraa wweerree mmeeaassuurreedd.. MMAALLDDII--TTOOFF mmaassss ssppeeccttrroommeettrryy iiss aa ppoowweerrffuull tteecchhnniiqquuee ffoorr ggaaiinniinngg mmeecchhaanniissttiicc iinnssiigghhttss inintotop oploylmymereizraiztaiotniorne arcetaiocntisonbas sebdasoend thoen ptrheese npcreesoernacbes eonr ceabosfemnceec hoafn imsmec-shpaenciisfimc-rsepaecctiiofinc preraocdtuiocnts p[3ro3]d.uFctigs u[r3e3]5. aFsighuorwes 5aa tyshpoicwasl Ma AtyLpDicIa-Tl OMFAmLDasIs-TsOpeFc tmruamss osfptehcetruhmyd roofx tyhl-et ehrymdirnoaxtyedl- PteBrAmiwnaittehdM PBn,AGP wCi=th4 M28n0,GPgC /=m 42o8l,0 agn/mdoitl,s aenndl aitrsg eendlasrpgeecdtr supmectrraunmgi nragngfrionmg fr3o0m25 3t0o253 3to0 033g0/0m g/oml oisl sish oshwonwinn iFni gFuigreur5eb .5bW. eWcea ncasnee seseev seenvesner sieesrioesf tohfe thPeB APBcAh acihnasitnhsa tthraetp reeaptewati twhitthhe tmhea mssaosfs aonf na-nB nA- uBnAi tu(n1i2t8 (1g2/8m go/ml,osle, eseFei gFuigreur5eb 5),ba),n adndth tehset srutrcutcutruarlaflo fromrmuulalsasf oforre eaacchhs seerrieiesso off ppoollyymmeerrss——ddeeppiicctteedd bbaasseedd oonn ththeeiri rmmasass—s—araer elisltiesdte idn TinabTlea b2l.e A2m.onAgm thoen gsevtheen sseervieesn, sseerriieess ,As iesr aie rselAatiivselay raebluantidvaenlyt aPbBuAn dsaenrtiePs.B ABasseerdie so.n Btahsee dmoansst heofm saesrsieosf Ase,r ieas sAtr,uactsutrraulc tfuorraml ufolarm cualna cbaen dbeepdicetpeidc teadnda nids iNsaN+Ha+OHCOHC2HCH2C2CHH2C2(HC2N(C)(NC)H(C3)HC3–)(Cn-–B(nA-)BnA–S)Cn–HSC2CHH22COHH2.O WH.hWenh ethnet hdeedgergeere eofo fppoolylymmeerrizizaattioionn ((DDPP)) wwaass 2233,, iittss nnuummbbeerr--aavveerraaggee mmoolleeccuullaarrw weeigighhtt( (MMnn)) ccoouulldd bbee ccaallccuullaatteedd aass 33115599.2.2g g//mmooll,, wwhhiicchh iiss vveerryy cclloossee ttoo tthhee mmeeaassuurreedd vvaalluuee ((33115588..44 gg//mmooll)).. Figure 5. (a) Mass-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI- Figure5.(a)Mass-assistedlaserdesorptionionizationtime-of-flightmassspectrometry(MALDI-TOF) sTpOeFct)r uspmecatnrudm(b )aenndl a(rbg)e denslpaergcterdu mspoefcttrhuemh yodfr othxey lh-tyedrmroixnyalt-etderPmBiAnaotebdta iPnBeAd boybtDaIiTnePdo fbny- BDAITwP itohf fne-eBdAm owlaitrhr afteioedo fm[no-BlaAr] /r[aAtiCoP Oof] /[Dn-IBXA=]1/[6A/C0.P5O/1]/iDnItXo lu=e n1e6a/0t.650/1◦ Cinf orto2l4uhen(eM at 60= °4C2 80fogr/ m24o l)h. n,GPC (Mn,GPC = 4280 g/mol). BasedonthecarefulanalysisofthestructuralformulasofsevenseriesofPBAsinTable2,wecan conjectureinterestingreactionsoccurringinthepolymerizationandclarifyhowtheterminalgroups Based on the careful analysis of the structural formulas of seven series of PBAs in Table 2, we can conjecture interesting reactions occurring in the polymerization and clarify how the terminal groups formed. As we mentioned previously, the end groups of PBA come only from the initiator, ACPO, and transfer agent, DIX. This can be further confirmed by the results of MALDI-TOF analysis. Both ends of the PBA capped with ACPO fragments include series D, E, and G; the transfer agent fragment, I—which was substituted by 2-mercaptoethanol after polymerization—occupies both ends of series B and F. Both end units of series A and C were ACPO and DIX fragments, respectively. Because the ACPO fragment has one terminal hydroxyl group, and after iodine at the ends of PBA was quantitatively substituted by KSCH2CH2OH (Figure 3), the PBA with hydroxyl groups at both ends was successfully synthesized, which is consistent with the results based on the analysis of 1H NMR spectrum. Table 2. Structural formulas of the PBA produced in DITP of n-BA, depicted based on MALDI-TOF Mass Spectrum. No. Structural formulaa (m/z)observation(g/mol) (m/z)calc. (g/mol) A Na+HO–CPO–(n-BA)n–ME–OH 3158.4 (n = 23) 3159.2 (n = 23) B Na+HO–ME–(n-BA)n–xylene–(n-BA)m–ME–OH 3232.5 (n2 = 23) 3228.2 (n2 = 23) Na+HO–CPO–(n-BA)n–xylene–(n-BA)m–xylene– C 3214.3 (n4 = 21) 3215.3 (n3 = 21) (n-BA)p–xylene–(n-BA)q–ME–OH Na+HO–CPO–(n-BA)n–xylene–(n-BA)m–xylene– D 3271.6 (n3 = 23) 3274.4 (n3 = 23) (n-BA)p–CPO–OH Polymers2018,10,219 10of16 formed. Aswementionedpreviously,theendgroupsofPBAcomeonlyfromtheinitiator,ACPO, andtransferagent,DIX.ThiscanbefurtherconfirmedbytheresultsofMALDI-TOFanalysis. Both endsofthePBAcappedwithACPOfragmentsincludeseriesD,E,andG;thetransferagentfragment, I—whichwassubstitutedby2-mercaptoethanolafterpolymerization—occupiesbothendsofseriesB andF.BothendunitsofseriesAandCwereACPOandDIXfragments,respectively.BecausetheACPO fragmenthasoneterminalhydroxylgroup,andafteriodineattheendsofPBAwasquantitatively substitutedbyKSCH CH OH(Figure3),thePBAwithhydroxylgroupsatbothendswassuccessfully 2 2 synthesized,whichisconsistentwiththeresultsbasedontheanalysisof1HNMRspectrum. Table2.StructuralformulasofthePBAproducedinDITPofn-BA,depictedbasedonMALDI-TOF MassSpectrum. No. Structuralformulaa (m/z)observation(g/mol) (m/z)calc.(g/mol) A Na+HO–CPO–(n-BA)n–ME–OH 3158.4(n=23) 3159.2(n=23) B Na+HO–ME–(n-BA)n–xylene–(n-BA)m–ME–OH 3232.5(n2=23) 3228.2(n2=23) C Na+HO–CPO–(n-BA)n–xylene–(n-BA)m–xylene– 3214.3(n =21) 3215.3(n =21) (n-BA)p–xylene–(n-BA)q–ME–OH 4 3 D Na+HO–CPO–(n-BA)n–xylene–(n-BA)m–xylene– 3271.6(n =23) 3274.4(n =23) (n-BA)p–CPO–OH 3 3 E Na+HO–CPO–(n-BA)n–CPO–OH 3196.2(n=23) 3194.2(n=23) F Na+HO–ME–(n-BA)n–xylene–(n-BA)m–xylene– 3181.1(n =21) 3180.3(n =21) (n-BA)p–xylene–(n-BA)q–ME–OH 4 4 G Na+HO–CPO–(n-BA)n–xylene–(n-BA)m–xylene– 3122.1(n =20) 3124.2(n =20) (n-BA)p–xylene–(n-BA)q–CPO–OH 4 4 a CPO: 4-cyano-1-pentanol (HOCH2CH2CH2(CN)(CH3)C); ME: 2-mercaptoethanol (SCH2CH2OH); xylene: CH2C6H5CH2;n2=n+m;n3=n+m+p;n4=n+m+p+q. Thereactionsoccurringinthepolymerizationcouldbegainedbasedonthepresenceorabsence ofmechanism-specificreactionproducts[33].BasedontheDITPmechanismlistedinScheme1,wecan depicthowsevenseriesofthePBAinTable2areformed;thereareprobablyseveralroutestoreach thesePBAspecies,andhereinwedescribeonlyoneofthem. Theintermediatesfortheformationof finalPBAspeciesaredepictedinScheme2. Theprimaryradicalsformedviadecompositionofthe ACPOinitiatesthepolymerizationofn-BAtoyieldPBAchainradicalI,andthenitreversiblyreacts withDIXtoformPBA–Iandp-iodomethylenebenzylradical. Thelatterinitiatesn-BAtopolymerize, yieldingthePBAchainradicalII.WhentheiodomethyleneofradicalIIreactswiththegrowingchain radicalorprimaryradicalandtheninitiatesthepolymerizationofn-BA,thegrowingchainradical III is formed. If the growing chain radical I continuously grows through chain propagation and degenerativechaintransfer,seriesAisformed. IrreversibleterminationofradicalIyieldsseriesE. SeriesBisformedthroughcontinuousgrowthofradicalII,andthenradicalIIIiscappedwithiodine viaitsreactionwithgrowingchainradicals. CouplingreactionofradicalIwithradicalIIIproducethe PBAspeciesIV;afterreactionwiththegrowingchainradicals,theresultantradicalIViscoupledto formseriesD.TerminationreactionsofradicalIIIwithradicalIIorradicalIV,respectively,yielded PBAspeciesVorVI.RadicalVisterminatedwithradicalIIIorwithradicalIV,respectively,toafford series F or series C, and series G is produced through coupling reaction of radical IV with radical VII.Therefore,thehydroxyl-terminatedPBAsobtainedbyDITPofn-BAareamixturecomposedofa seriesofPBAwithdifferentnumbersofDIXunitsandterminalspecies. Indeed,thereactionsinthe DITPofn-BAaremorecomplicatedthanthatdescribedabove;allthesereactionswillinfluencethe polymerizationkineticsandtheformationofpolymerchains,whichwillbediscussedlater.