Article Phosphotungstate-Based Ionic Silica Nanoparticles Network for Alkenes Epoxidation XiaotingLi,PingpingJiang*,ZhuangqingWangandYuandanHuang Received:28October2015;Accepted:14December2015;Published:24December2015 AcademicEditor:MichalisKonsolakis TheKeyLaboratoryofFoodColloidsandBiotechnology,MinistryofEducation, SchoolofChemicalandMaterialEngineering,JiangnanUniversity,Wuxi214122,China; [email protected](X.L.);[email protected](Z.W.);[email protected](Y.H.) * Correspondence:[email protected];Tel.:+86-135-0619-6132 Abstract: An inorganic-organic porous silica network catalyst was prepared by linking silica nanoparticles using ionic liquid and followed by anion-exchange with phosphotungstate. Characterization methods of FT-IR, TG, SEM, TEM, BET, etc., were carried out to have a comprehensive insight into the catalyst. The catalyst was used for catalyzing cyclooctene epoxidationwithhighsurfacearea,highcatalyticactivity,andconvenientrecovery. Theconversion and selectivity of epoxy-cyclooctene could both reach over 99% at 70 ˝C for 8 h using hydrogen peroxide (H O ) as an oxidant, and acetonitrile as a solvent when the catalyst was 10 wt. % 2 2 ofcyclooctene. Keywords: silicananoparticles;ionicliquid;network;phosphotungstate;catalyst;epoxidation 1. Introduction Inorganic-organichybrid[1–8]materialshaveattractedconsiderableinterestasthecombination of the features of different parts can generate high performance. As the development of nanoscale materials, SiO has indeed stimulated remarkable scientific interest because of its excellent 2 performance and promising applications in scientific and technological fields. In contrast to other inorganicmaterials,thepreparationofSiO nanoparticleshasbeenverymaturewithawidesource 2 of raw materials, and they possess the merits of high specific surfaces, as well as excellent thermal stabilities. Furthermore, the presence of a large number of silanol (Si–OH) groups on the surface makesiteasilyforsurfaceorganicfunctionalization[9,10]. Ionicliquids,aclassofnewtypeofgreen environmental protection organic compounds with outstanding properties, were introduced as the organic part, recently. The resulting materials can be applied into numerous fields, like catalysts, anionexchange,selectivegastrapping,drugdelivery,orelectrochemistry[11]. The modification of silica nanoparticles with ionic liquids has been already reported by some researchers [12–14]. Ionic liquids are usually just grafted or absorbed onto the surface for next use. However, this is no longer a hot spot and novel method. Meanwhile, it remains separation problemsifthenanoparticlesaresmallerthanacertainsize. Forafewyearsnow,thenewly-arising challenge in the field of nanoparticle research is focusing on the development of specific materials based on assemblies of nanoparticles, which approaches to make use of the nanoparticle collective properties [15–20]. Thus, a silica network is being prepared by connecting silica nanoparticles with ionicliquidtotaketheadvantageofcovalentlinkofionicliquidbytwodifferentparts. Epoxidesareimportantrawmaterialsinchemicalindustrialproduction[21]. Polyoxometalates (POMs),asisknowntoall,havebeenwidelyusedasepoxidationcatalystswithH O fortheirhigh 2 2 efficient active centers [22–24]. However, POMs, themselves, are low efficient and soluble in some Catalysts2016,6,2;doi:10.3390/catal6010002 www.mdpi.com/journal/catalysts Catalysts2016,6,2 2of13 epoxidation systems which results in the difficulty in separation of the catalysts. Therefore, ionic liquid-basedPOMhybridcatalystscomeintobeing. In this study, we first prepared a silica network by connecting silica nanoparticles with covalent-linked ionic liquid. This material was proved to be porous with high surface area. Phosphotungstic acid anions were then introduced into the material by ion exchange between Keggin-type H PW O and ionic liquid as well as protonation of amino group. Ionic liquid 3 12 40 had played an important role in two aspects: linking silica nanoparticles and introduction of an active center. The catalysts were used in catalytic epoxidation of olefin for the first time. Structural characteristics and catalytic performance of as-prepared catalysts were carried out to have a comprehensive insight into the catalyst. The study potentially propels the development of nanoparticle networks as promising materials for various fields to take advantage of the collective propertiesofnanoparticles. 2. ResultsandDiscussion 2.1. Characterization 2.1.1. FT-IRAnalysis ThebasicmodificationmoietiesontheSiO particleswerecharacterizedbyFT-IR,whichwere 2 showninFigure1. Thebandsat3450and1630cm´1 werecorrespondingtostretchingandbending vibrationsofsurfaceSi–OHgroupsonthesurfaceofSiO . Aftergraftingwithsilanecouplingagent, 2 thepeakintensitydecreasedandnewbandsthatassignedtotheC–Hstretchingandbendingrocking moderespectivelyappearedintheregionof2970cm´1and1460cm´1(Figure1b–e),whichindicated Catalytshtes s2u0c1c6es, s6fu l functionalization on the surface of SiO particles. The other bands at 1100 cm´1 and 3 2 814cm´1wereattributedtosymmetricandanti-symmetricstretchingvibrationofSi–O–Si,andband a bandat 9a6t0 8cm90´ 1cwma−s1a tatrpipbeuaterdedt oitnh eFSiig–Ourset re1tech, inwghvicibhr atwioans ofaSssi–iOgnHe.dF otroP Wasy(0m.0m58e)t/rSiciO 2stIrmet+cChli´ng of SiO , a band at 890 cm´1 appeared in Figure 1e, which was assigned to asymmetric stretching of W–O –W2 in the corner-shared octahedral of Keggin-typeHPW. Other characteristic bands at 1080, 983, b W–O –W in the corner-shared octahedral of Keggin-type HPW. Other characteristic bands at 1080, b and 80958 3c,man−1d w80e5rec mal´l 1owveerrleaaplpleodv ewrliatphp tehde wbaitnhdtsh eofb aSnidOs2o. fSiO . 2 (a) a.u.) (b) 2970 1630 960 e ( (c) c n mitta (d) 3440 1460 ans (e) 814 r T 890 1100 4000 3500 3000 2500 2000 1500 1000 500 Wavenumber/cm-1 Figure1.FT-IRspectraof(a)SiO ;(b)SiO -Im;(c)SiO -Cl;(d)SiO Im+Cl´SiO ;(e)PW(0.058)/SiO 2 2 2 2 2 2 FiguIrme +C1l.´ FSTiO-IR. spectra of (a) SiO2; (b) SiO2-Im; (c) SiO2-Cl; (d) SiO2 Im+Cl− SiO2; 2 (e) PW(0.058)/SiO Im+Cl− SiO . 2 2 2.1.2. ThermalStabilityandStructure 2.1.2. TherTmhael TSGtabanilaitlyys aesndo fSStriOuc,tuSrieO -Cl, SiO -Im, SiO Im+Cl´ SiO , and PW (0.058)/SiO Im+Cl´ 2 2 2 2 2 2 SiO wereshowninFigure2. ForthepureSiO nanoprticles(Figure2a),theweightlossof5.65wt.% 2 2 Thec oTuGld abneaolnylsyeos bosfe rSvieOd2b, eSfoirOe21-0C0l˝, CS,iwOh2-iIcmhw, SasiOas2s iIgmn+eCdlt−o SthieOd2e, saonrdp tiPoWno f(0w.0at5e8r.)/NSoiOw2e iIgmh+tClols−s SiO2 were schoouwldn bine sFeiegnureev e2n. Fwoitrh ththee piunrcere SaisOing noafntoemprptiecrlaetsu r(eFitgou8r0e0 2˝aC)., Itnher ewaleitiyg,htth leosfosr omfe 5d.6io5n wictu. n%it scould 2 be only observed before 100 °C, which was assigned to the desorption of water. No weight loss could be seen even with the increasing of temperature to 800 °C. In reality, the formed ionic units of imidazolium presents a higher thermal stability than the aromatic precursors. The precursors started to decompose before 200 °C, while the imidazolium mainly decomposes around 300 °C. From Figure 2b,c, SiO -Cl started to decompose at 180 °C, SiO -Im started to decompose at 120 °C, and the 2 2 main weight loss was around 400 °C. From Figure 2d, the first stage ranging from 25 to 120 °C was ascribed to the elimination of adsorbed water. After 120 °C the unreacted organic groups started to decompose and the weight loss around 300 °C was mainly attributed to the decomposition of imidazolium ionic units, which could verify the occurrence of nucleophilic reactions, on one hand. For the PW(0.058)/SiO Im+Cl− SiO (Figure 2e), the mass loss after 300 °C also contained the collapse of 2 2 PW anions in the remainder form of P O and WO . 2 5 3 2.1.3. SEM, EDS, TEM, and DLS Characterization The morphology changes between SiO nanoparticles and the modified product of SiO -Cl, SiO -Im, 2 2 2 and SiO Im+Cl− SiO were provided by the SEM and TEM images presented in Figure 3. Figure 3a,b 2 2 were the SEM images for SiO nanoparticles before reaction, which presented scattered and small 2 particles size of SiO . The particle size could be observed in TEM in Figure 3f,g with an average of 2 15 nm diameter which was in slight agglomeration. After functionalization, the particle morphology of SiO -Cl and SiO -Im had almost no change (showed in (c) and (d)) compared to SiO nanoparticles. 2 2 2 Figure 3e,h showed the SEM and TEM micrographs after linking nanoparticles through the ionic Catalysts2016,6,2 3of13 of imidazolium presents a higher thermal stability than the aromatic precursors. The precursors started to decompose before 200 ˝C, while the imidazolium mainly decomposes around 300 ˝C. FromFigure2b,c, SiO -Clstartedtodecomposeat180˝C,SiO -Imstartedtodecomposeat120˝C, 2 2 and the main weight loss was around 400 ˝C. From Figure 2d, the first stage ranging from 25 to 120˝Cwasascribedtotheeliminationofadsorbedwater. After120˝Ctheunreactedorganicgroups Cstaatratleydsttso 2d0e1c6o,m 6 poseandtheweightlossaround300˝Cwasmainlyattributedtothedecomposition4 ofimidazoliumionicunits,whichcouldverifytheoccurrenceofnucleophilicreactions,ononehand. lFiqouridth-leikPe Wb(o0n.0d5. 8T)/hSei OproIdmu+cCt,l ´byS iOobse(Frvigautiroen 2oef) , “thiselamndass”s, lcoosnsnaefcteterd3 0in0to˝ Ca allasorgecro ngtaroinuepd, ltihkee 2 2 scpoolnlagpes-ecaokfeP wWitahn diiosnpserinsetdh heorleems.a inderformofP O andWO . 2 5 3 100 (b) 95 (a) %) s ( 90 (e) as (d) M 85 (c) 80 75 100 200 300 400 500 600 700 800 Temperature (oC) FFigiguurere2 .2T. hTehrmeromgoragvriamveimtriectrciucr vceusrvoefs( ao)fS (iOa)2 ;S(ibO)S;i O(b2)-C Sli;O(c)-SCiOl; 2(-cIm) S;i(Od)S-IiOm2; I(md)+ CSli´OS iIOm2+;Canl−d 2 2 2 2 (e)PW(0.058)/SiO Im+Cl´SiO . SiO ; and (e) PW2(0.058)/SiO2 Im+Cl− SiO . 2 2 2 2.1.3. SEM,EDS,TEM,andDLSCharacterization (a) (b) (c) (d) (e) The morphology changes between SiO nanoparticles and the modified product of SiO -Cl, 2 2 SiO -Im, andSiO Im+Cl´ SiO wereprovidedbytheSEMandTEMimagespresentedinFigure3. 2 2 2 Figure 3a,b were the SEM images for SiO nanoparticles before reaction, which presented scattered 2 and small particles size of SiO . The particle size could be observed in TEM in Figure 3f,g with 2 anaverageof15nmdiameterwhichwasinslightagglomeration.Afterfunctionalization,theparticle morphologyofSiO -ClandSiO -Imhadalmostnochange(showedin(c)and(d))comparedtoSiO 2 (f) 2 (g) (h) 2 nanoparticles.Figure3e,hshowedtheSEMandTEMmicrographsafterlinkingnanoparticlesthrough the ionic liquid-like bond. The product, by observation of “islands”, connected into a larger group, likesponge-cakewithdispersedholes. In order to get a profound insight into the microscopic structure, scanning SEM-energy dispersive spectroscopy (EDS) elemental mapping images of catalyst PW(0.058)/SiO -Im-SiO was 2 2 produced,and(ti)h eresultsweresShio wninFigure3i.OSi ,O,N,Cl,P,andWN wereuniformlydistributed inthiscatalyst. DLS (Dynamic Light Scattering) was carried out after dispersing the samples in ethanol with previoussonicationandtheresultswereshowninFigure4. Italsoindicatedthattheparticlesizeof the product SiO Im+Cl´ SiO was much larger than the one before reaction, which corresponded 2 2 to the SEM and TEMCmlicrographs. ForPF igure 4A, a diffraWction peak could be observed around 30nm.TheresultwaslargerthanthemeasurementbyTEMmicrographs,whichwasduetotheslight agglomeration. WhenreactingwithN-(3-triethoxysilylpropyl)-4,5-dihydroimidazol,theparticlesize wasslightlyincreasedinFigure4B.Nevertheless,fortheresultedSiO Im+Cl´SiO ,themostaverage 2 2 sizeshowedinFigure4Cwasat700nmafternucleophilicreaction. Thesmallersizedistributionwas duetotheincompleteorpartialreactionofthefunctionalizedsilicaparticles. Overall, thissizewas Figure 3. SEM, TEM and EDS images at different magnifications. (a,b) for SEM of SiO ; 2 muchlargerthanSiO ,alsoindicatingthechangeafterthereaction. (c) for SEM of 2SiO -Cl; (d) for SEM of SiO -Im; (e) for SEM of SiO Im+Cl− SiO ; 2 2 2 2 (f,g) for TEM of SiO ; and (h) for TEM of SiO Im+Cl− SiO respectively; (i) for EDS 2 2 2 elemental mapping images of the Si, O, N, Cl, P, and W, respectively. Catalysts 2016, 6 4 liquid-like bond. The product, by observation of “islands”, connected into a larger group, like sponge-cake with dispersed holes. 100 (b) 95 (a) %) s ( 90 (e) as (d) M 85 (c) 80 75 100 200 300 400 500 600 700 800 Temperature (oC) Figure 2. Thermogravimetric curves of (a) SiO ; (b) SiO -Cl; (c) SiO -Im; (d) SiO Im+Cl− 2 2 2 2 Catalysts2016,6,2 4of13 SiO ; and (e) PW(0.058)/SiO Im+Cl− SiO . 2 2 2 (a) (b) (c) (d) (e) (f) (g) (h) Catalysts 2016, 6 5 In order to get a profound insight into the microscopic structure, scanning SEM-energy dispersive spectroscopy (EDS) elemental mapping images of catalyst PW(0.058)/SiO -Im-SiO was produced, and 2 2 the results were( is) hown in Figure S3ii . Si, O, N, Cl, P, aOn d W were uniformNly distributed in this catalyst. DLS (Dynamic Light Scattering) was carried out after dispersing the samples in ethanol with previous sonication and the results were shown in Figure 4. It also indicated that the particle size of the product SiO Im+Cl− SiO was much larger than the one before reaction, which corresponded to the SEM and 2 2 TEM micrographs. ForC Fligure 4A, a diffrPa ction peak could bWe observed around 30 nm. The result was larger than the measurement by TEM micrographs, which was due to the slight agglomeration. When reacting with N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol, the particle size was slightly increased in Figure 4B. Nevertheless, for the resulted SiO Im+Cl− SiO , the most average si ze showed in Figure 4(C) 2 2 was at 700 nm after nucleophilic reaction. The smaller size distribution was due to the incomplete or FigFuirgeu r3e.3 .SSEEMM,, TTEEMMan adnEdD ESiDmSag iemsaatgdeisff earte ndtimffaegrennifitc amtiaognsn.i(fai,cba)tfioornSsE.M (ao,fbS)i Ofo2;r( cS)EfoMrS EoMf SoifO2; partia(lc r)e SafiocOrt2i -oSCnlE; oM(df) tfohofre SSfEuiMOncot-fiCoSilnO; a2(l-idIzm)e ;df(o es)ri floSircEaSM EpMa rootffi cSSlieOisO2. IOm-I+vmCe;lr´ a(lSeli,)O t2fho;i(srf ,gsSi)EzfoeMr wT EoaMsf mSofiuOSciOh 2Il;maar+ngCdel(r−h t)hSfoaiOrn S;i O 2, also indicatinTgE tMheo cfhSiaOn2gIem a+Cftle´r2 StihOe2 rreeaspcetciotivne. ly;(i)forEDSel2ementalmappingimagesofthe2S i,O,N,Cl,P, 2 (f,ga) nfdoWr ,TreEspMec toivfe lSy.iO2; and (h) for TEM of SiO2 Im+Cl− SiO2 respectively; (i) for EDS elemental mapp ing images of the Si, O, N, Cl, P , and W, respectively. 1.0 1.0 1.0 0.8 0.8 0.8 Distribution/a.u.00..46 Distribution/a.u.00..46 Distribution/a.u.00..46 0.2 0.2 0.2 0.0 0.0 0.0 0.1 1 10 100 1000 10000 0.1 1 10 100 1000 10000 0.1 1 10 100 1000 10000 Radius/nm Radius/nm Radius/nm 1 (A) (B) (C) Figure4.DLSmeasurementof(A)thestartingSiO nanoparticles;(B)SiO -Im;and(C)resultantSiO Figure 4. DLS measurement of (A) the s2tarting SiO nanop2articles; (B) SiO -Im2; and 2 2 Im+Cl´SiO . (C) resultant 2SiO Im+Cl− SiO . 2 2 2.1.4. NitrogenSorption 2.1.4. Nitrogen Sorption The porous characteristic of the materials were investigated by Brunauer-Emmet-Teller (BET) method. The N adsorption-desorption isotherms and corresponding pore size distribution curves The porous cha2racteristic of the materials were investigated by Brunauer-Emmet-Teller (BET) were shown in Figure 5 (the curves of PW/SiO Im+Cl´ SiO were particularly similar, so 2 2 methPoWd.( 0T.0h5e8 )N/S2i OadsIomrp+Ctiol´n-SdiOesowrpatsiocnh oisseotahserrempsr easnendt actoivrree).spAolnldsianmgp pleosred isspizleay deidsttryibpuictailonty pcue-rIvVes were 2 2 showisno tihne rFmigsuwriet h5a (ctlheaer caudrsvoerps toiofn P-dWes/oSripOtio nImhy+sCtelr−e sSiisOloowpsearet thpearrteilcautilvaerlpyr essismurielaorf, 0s.o8 <PPW/(P0.0<518)/SiO 2 2 0 2 Im+C(Fl−ig SuirOe52 ,wleafts) cahsowseel laass rberporaedsepnotraetsivizee).d Aistlrli bsaumtiopnle(Fs idgiusrpel5a,yreigdh tty).pFicoarlt htyepSeiO-I2Vn aisnootphaerrtmiclse sw,iththe a clear poresizewasmainlydistributedinlessthan2nm,whichwasduetothemicroporesofnanoparticles adsorption-desorption hysteresis loops at the relative pressure of 0.8 < P/P < 1 (Figure 5, left) as well 0 as broad pore size distribution (Figure 5, right). For the SiO nanoparticles, the pore size was mainly 2 distributed in less than 2 nm, which was due to the micropores of nanoparticles themselves. The size formed above 2 nm was mainly due to the accumulation between the particles. However, when linked by ionic liquid, the SiO network and its catalyst showed more regular in pore size distribution between 2 20–40 nm. Data of surface area, pore diameter, and pore volume were presented in Table 1. The BET specific surface area of the prepared SiO particles (entry 1) was as high as 381 m2g−1 and the average 2 pore size was 11.2 nm. When modified by organic reagents and then linked by nucleophilic reaction, specific surface of SiO network (entry 2) was obviously lower than the pure SiO due to the introduction 2 2 of the organic moieties. After introducing phosphotungstic acid anions into the material by ion exchange, the specific surface of PW(x)/SiO Im+Cl− SiO (entries 3–6) also decreased and were lower than the 2 2 Catalysts2016,6,2 5of13 themselves. Thesizeformedabove2nmwasmainlyduetotheaccumulationbetweentheparticles. However, when linked by ionic liquid, the SiO network and its catalyst showed more regular in 2 poresizedistributionbetween20–40nm. Dataofsurfacearea,porediameter,andporevolumewere presentedinTable1.TheBETspecificsurfaceareaofthepreparedSiO particles(entry1)wasashigh 2 as381m2¨g´1 andtheaverageporesizewas11.2nm. Whenmodifiedbyorganicreagentsandthen linkedbynucleophilicreaction,specificsurfaceofSiO network(entry2)wasobviouslylowerthan 2 thepureSiO duetotheintroductionoftheorganicmoieties.Afterintroducingphosphotungsticacid 2 anionsintothematerialbyionexchange,thespecificsurfaceofPW(x)/SiO Im+Cl´SiO (entries3–6) 2 2 also decreased and were lower than the SiO network. Meanwhile, compared to the pure SiO , the 2 2 SiO networkanditscatalystsexhibitedanincreaseofporesizeandporevolume. Inparticular,the 2 poresizeseemedmorecentralized. Thisincreasedthecontactareaofthesubstrateandcatalystsand led to better catalytic effect. Meanwhile, increased PW anions loading of PW(x)/SiO Im+Cl´ SiO 2 2 ledtoagradualdecreaseinporevolumeandaverageporesize(entries3–6). (A)  (B) Figure5.Nitrogenadsorption-desorptionisotherms(A)andporesizedistribution(B)ofthesamples SiO ,SiO Im+Cl´SiO ,andPW/SiO Im+Cl´SiO . 2 2 2 2 2 Table1.BETparametersoftheSiO ,SiO Im+Cl´SiO ,andPW(x)/SiO Im+Cl´SiO . 2 2 2 2 2 Entry Compound SBET(m2¨g´1) Vp(cm3¨g´1) AveragePoreSize(nm) 1 SiO 381 0.93 11.2 2 2 SiO Im+Cl´SiO 242 1.50 24.1 2 2 3 PW(0.035)/SiO Im+Cl´SiO 182 1.24 24.0 2 2 4 PW(0.058)/SiO Im+Cl´SiO 176 1.07 24.0 2 2 5 PW(0.074)/SiO Im+Cl´SiO 168 1.01 22.4 2 2 6 PW(0.17)/SiO Im+Cl´SiO 159 0.93 20.3 2 2 2.1.5. MoreEvidenceoftheSynthesisoftheNetwork Inordertofurtherconfirmtheoccurrenceofnucleophilicsubstitutionbetweentheimidazoline functional group and chloroalkyl group, anion exchange experiment was carried out as an indirect proof. Once the nucleophilic substitution happened, the chloride ion was easily exchanged by the fluorinatedaniontoobtaintheSiO Im+BF ´ SiO andNaCl. First,wedetectedchlorideionsinthe 2 4 2 solvent and washing phase by the signature of the halide salts in the X-ray diffraction pattern after 1 Catalysts2016,6,2 6of13 Catalysts 2016, 6 7 drying (Figure 6). In the XRD pattern, the obtained salt reflection was marked with a star and was Catalysts 2016, 6 7 consistentwithNaCl. TheotherBraggpeaksbelongedtothefluorinatedsaltwhichwasinanexcess the neiwnloyr deexrcthoacnognefidr mantihoense xccohualndg eb.e Noebxvt,ioEuDslXy aonbaslyesrivseodf wthheilhey bthried bmoarotenr iawlaSsiO h2idImde+nB Fb4y´ tShieO 2c,arbon the neowbltyai neexdchafatnergtehde aexncihoannsg ceoruealdct iboen aolbsovisohuoswlye dotbhseeerxviestde nwcehiolfen tehwel yb-oinrtorno dwucaesd haindidoenns (bFyig uthree 7c).arbon peak. After the exchange reaction, it was noted that chlorine could still be observed in a small amount. peak. ATyfpteicra tlhpee aekxschoafnflgueo rrienaecftrioomn, tiht ewnaesw nlyoteexdc hthanatg ecdhlaonriionnes ccoouulldd sbteilol bbvei ooubssleyrovbesde rivne ad swmhaillel tahmeount. The presence of chlorine was due to the residue alkyl chloride groups which did not react with APTES boronwashiddenbythecarbonpeak. Aftertheexchangereaction,itwasnotedthatchlorinecould The presence of chlorine was due to the residue alkyl chloride groups which did not react with APTES or the srteilslibdeueo bcshelrovreidnein ioanssm walhliacmh owuenrte. Tnhoet epxrecsheanncgeeodf. chlorine was due to the residue alkyl chloride or the residue chlorine ions which were not exchanged. groupswhichdidnotreactwithAPTESortheresiduechlorineionswhichwerenotexchanged. u.) ensity(a.u.)Intensity(a. ((aa)) ** ** ** ** ** ** nt I (b) (b) 10 20 30 40 50 60 70 10 20 2 T3h0eta(degre4e0s) 50 60 70 2 Theta(degrees) Figure 6. XRD analyses of (a) the exchange solvent, after separation and washing; Figure 6. XRD analyses of (a) the exchange solvent, after separation and washing; (b) NaBF . Figure 6. XRD analyses of (a) the exchange solvent, after separation and was4hing; (b) NTahBeoFb4t.a Tinhede soablttareiflneecdti osnalwt arsefmleacrktieodnw withasa mstaarrakneddw waistcho an ssistatern atnwdit hwNasa Cclo.nsistent with NaCl. (b) NaBF . The obtained salt reflection was marked with a star and was consistent with NaCl. 4 Figure7.EDXspectraoftheresultingmaterials. Figure 7. EDX spectra of the resulting materials. Figure 7. EDX spectra of the resulting materials. 2.2. CatalyticPerformances 2.2. Catalytic Performances 2.2. CatalyItticis Pkenrofwornmtaonaclelst hat the Keggin-type [PW O ]3´ (PW) can be degraded to peroxo-active 12 40 It issp kencioews,n[P tWo 4aOll8 (tOha2t) 8t]h3´e sKpeegcigeisn,-btyypexec [ePssWhydOrog]e3n− p(PerWox)i dcea,nw bheic dheigsrthadeeadct itvoe psepreocxieos-iancatilvkeen sepsecies, 12 40 [PWIt iOse pk(onOxoidw)ant]i3 o−ton s sa[pl2le5 ct]h.ieTasth ,e thsbeoy lKv eeengxtgcheianss-sta yghpryeed a[trPoinWgfle1un2e Onpc40ee]ro3o−nx (tihPdeWea, c)t wicvahintiyc bhoe f cidaset agtlryhatedi ceradec attcoitv ipoe nersaopnxedoca-icaeecst toivinneit rsialpelekceineess, 4 8 2 8 [PW4Ois8c(oOm2)m8]o3n− lysupseecdieisn, epboyx ideaxtcioenssr eahcytidornoagseann epfefircoiexnidteso, lvwenhti.cMh oirse ovthere, uasicntgivHe 2Osp2eacsiaens oixny geanlkenes epoxidations [25]. The solvent has a great influence on the activity of catalytic reaction and acetonitrile sourcecandogreatbenefitsontheenvironmentandindustry[26]. Thus,Table2listedthecatalytic epoxidations [25]. The solvent has a great influence on the activity of catalytic reaction and acetonitrile is compmerofonrlmy aunsceedo ifnd eifpfeorxeindtactaiotanl yrsetascftoironth aese apno xeidffaitciioennto fsocylvcelonotc. tMenoerienoavceert,o unsitirnilge HusiOng aasq uaeno uosxygen 2 2 is com3m0%onHly Ouseads iann eopxoidxaindta.tioTnh erereascutilotsns haso waned efthfiactiethnet scoatlavleynstt. PMWo/rSeioOveIrm, u+sCiln´g SHiO2O2h aads manu cohxygen source can d2o 2great benefits on the environment and industry [26]. Thus2, Table 2 lis2ted the catalytic sourceb ectatenr dcaot aglyretiact ebffeencteftihtasn otnh ethKee gegnivni-rtoynpemHenPt WandO ind.uOstnrey r[e2a6so].n Twhausst,h Teasbulpee r2-h lyidstreodp hthobei ccaotfalytic 3 12 40 performance of different catalysts for the epoxidation of cyclooctene in acetonitrile using aqueous 30% H PW O , which made it difficult to contact with the oily substrates. Meanwhile, the cations of perform3ance1 2of4 d0ifferent catalysts for the epoxidation of cyclooctene in acetonitrile using aqueous 30% HH2OO2 aiamss iaadnna zoooxxliiidudamanntat..n TTdhhNee H rree2ss+uuillnttssi msshhidooawwzeeoddli n tthehaamtt atthhdeee cictaaettaaasllyiyessrtt fPPoWrWth//SSeiirOOed2 oIIxmmo++fCCPllW−− SS.iPiOOhy2 shhiacaaddl mmlouaudcchihn bgbeeottftteeHrr PccWaattaallyyttiicc 2 2 2 2 effect than the Keggin-type H PW O . One reason was the super-hydrophobic of H PW O , which 3 12 40 3 12 40 effect than the Keggin-type H PW O . One reason was the super-hydrophobic of H PW O , which made it difficult to contact wit3h the1 2oil4y0 substrates. Meanwhile, the cations of imidazol3ium1 a2nd40 NH + in 2 made it difficult to contact with the oily substrates. Meanwhile, the cations of imidazolium and NH + in 2 imidazoline made it easier for the redox of PW. Physical loading of HPW on the pure SiO nanoparticles 2 imidazoline made it easier for the redox of PW. Physical loading of HPW on the pure SiO nanoparticles 2 Catalysts2016,6,2 7of13 on the pure SiO nanoparticles was carried out and the catalytic activity was very low, which also 2 illustrated the serviceability of SiO Im+Cl´ SiO for loading the PW anions. In order to further 2 2 compare the catalytic activity of the network catalysts with traditional silica grafted ionic liquid catalyst, we also performed a catalytic reaction in the presence of the imidazolium and the silica particleslabeledasHPW/SiO -ILwhichwaspreparedbynucleophilicreactionbetweenSiO -Cland 2 2 methylimidazole, and then reacted with phosphotungstic acid. The catalytic activity showed that theconversionwaslowerthanthenetworkcatalystswithsimilarselectivity(Table2,entry4),which demonstratedthattheformednetworkcatalystscouldleadtohighconversionandselectivity. Table2.Catalyticperformancesofcyclooctenewithvariouscatalysts. Conversion(%) Selectivity(%) Catalysts 2h 4h 6h 8h 2h 4h 6h 8h SiO - - - - - - - - 2 HPW 4.9 8.6 11.2 14.2 70.3 67.9 61.8 43.2 HPW/SiO 0.8 1.6 4.4 6.6 36.8 34.5 35.8 32.4 2 HPW/SiO -IL 30.5 52.7 72.4 79.8 98.7 98.1 97.4 97.0 2 PW(0.035)/SiO Im+Cl´SiO 54.3 68.4 76.5 84.1 98.5 98.2 97.9 96.9 2 2 PW(0.058)/SiO Im+Cl´SiO 77.2 88.8 94.4 99.4 99.4 99.4 99.3 99.2 2 2 PW(0.074)/SiO Im+Cl´SiO 68.5 78.2 91.1 93.5 99.3 98.4 98.9 98.9 2 2 PW(0.17)/SiO Im+Cl´SiO 45.3 63.6 70.2 77.6 98.7 98.1 98.7 98.2 2 2 Reaction conditions: cyclooctene: 2 mmol, acetonitrile: 5 mL, H2O2: 6 mmol, catalysts: 0.02 g, temperature70˝C. Furthermore, Table 2 also showed that the loading of PW anions of PW/SiO Im+Cl´SiO 2 2 affected the catalytic activity of the catalysts. This was correlation with the amount of active sites inthecatalystandtheinsidestructureofmaterial. Obviously, PW(0.058)/SiO Im+Cl´SiO showed 2 2 the best activity. When the loading of PW anions was less than 0.058, the conversion decreased accordingly. However,excessivePWloadingresultedintheagglomerationofexcessiveHPWinthe channel,whichmightchangethespecificsurfaceareaandporevolume,therefore,ledtothedecrease ofcatalyticactivity. ToinvestigatetheimportanceoftheILmoiety,theimidazolinebasedPW/SiO -Imwasprepared 2 bystirring0.6gHPWwith1gSiO -Im,andtheloadingofPWwereca. 0.082mmol/g. Thecatalytic 2 activity and reusability were compared in Table 3. Imidazoline-modified SiO can be protonated 2 withHPW.TheresultsshowedthatthecatalystofPW/SiO -Imofferedevenhigherconversionthan 2 PW(0.058)/SiO Im+Cl´SiO inthefirstrun. ThisisbecauseoftheincreasedprotonatingofSiO -Im 2 2 2 per unit mass leading to more PW loading, and the PW(0.058)/SiO Im+Cl´SiO also contains the 2 2 part of SiO -Cl. However, the reusability of PW/SiO -Im was far less active than the catalyst of 2 2 PW(0.058)/SiO Im+Cl´SiO . Thereweretwopossiblereasons: onewasthatthestabilityofNH +in 2 2 2 imidazolinewaslowandtheotherwasthattherecoveryefficiencyofindividualSiO nanoparticles 2 wasmuchlowerthanthecollectiveSiO networkonaccountofthecatalystssize. 2 Table 3. Catalytic reusability of PW(0.058)/SiO Im+Cl´SiO and PW(0.082)/SiO -Im for the 2 2 2 epoxidationofcyclooctene. PW(0.058)/SiO Im+Cl´SiO PW(0.082)/SiO -Im Runa 2 2 2 Conversion(%) Selectivity(%) Conversion(%) Selectivity(%) 1 94.4 99.3 96.0 98.2 2 88.7 97.5 27.1 87.3 3 82.1 95.1 25.8 81.6 4 75.2 94.6 18.6 78.3 The reusability experiment was carried out by adding the residual catalyst in the next reaction after centrifugation and drying without any change of other components. a Reaction conditions: cyclooctene: 2mmol,acetonitrile:5mL,H2O2:6mmol,catalysts:0.02g,temperature:70˝C,reactiontime:6h. Catalysts 2016, 6 9 Table 3. Catalytic reusability of PW(0.058)/SiO Im+Cl−SiO and PW(0.082)/SiO -Im for 2 2 2 the epoxidation of cyclooctene. PW(0.058)/SiO Im+Cl−SiO PW(0.082)/SiO -Im Run a 2 2 2 Conversion (%) Selectivity (%) Conversion (%) Selectivity (%) 1 94.4 99.3 96.0 98.2 2 88.7 97.5 27.1 87.3 3 82.1 95.1 25.8 81.6 4 75.2 94.6 18.6 78.3 The reusability experiment was carried out by adding the residual catalyst in the next reaction after centrifugation and drying without any change of other components. a Reaction conditions: cyclooctene: 2 mmol, acetonitrile: 5 mL, H O : 6 mmol, catalysts: 0.02 g, temperature: 70 °C, reaction time: 6 h. 2 2 2.2.1. Effects of Temperature and Time Catalysts2016,6,2 8of13 Each chemical reaction was accompanied by thermal effects. The same reaction carried out at differ2e.n2.t1 .teEmffepcetrsaotufrTeesm wpeorualtdu rreeasnudlt Tiinm qeuite different results. The reaction time was an important basis to judge it effective or not. The effects of temperature and time on the epoxidation of cyclooctene using Each chemical reaction was accompanied by thermal effects. The same reaction carried out at catalydsitf fPerWen(t0t.e0m5p8e)/rSatiuOr2eIsmw+oCull−dSirOes2u wlteinreq suhitoewdnif fienr eFnitgruerseu l8ts. .ItT wheasre oabctsieornvteidm ethwata swaitnh imthpeo irntacnretase of tempebraastiusrteo, jtuhdeg emiotleefcfueclatirv eenoerrgnyot,. anTdh ereelfafetcivtse ocfotnemtepnet raotfu raecatinvdatetidm emoonletchueleesp oinxicdraetaiosend,o fwhich cycloocteneusingcatalystPW(0.058)/SiO Im+Cl´SiO wereshowninFigure8. Itwasobservedthat increased the effective collision between t2he reactant2 molecules, thereby improving the conversion. with the increase of temperature, the molecular energy, and relative content of activated molecules However, the increase of temperature also increased the possibility of ring rupture, resulting in the increased,whichincreasedtheeffectivecollisionbetweenthereactantmolecules,therebyimproving decretahsee coofn vseerlesicotniv.iHtyo. wWevheern, ttheeminpcerreaatsuereo freteamchpeedra 7tu0r e°Cal,s othien crreeaacsteidonth heapdo tsesnibdielidty toof brainlagnrcuep. tHuroew, ever, the corensvueltrisnigonin dtehcerdeaescreeda saet o8f0s °eClec atinvdit yt.hWe sheelnectetimvipteyr awtuarse irne aac hsehdar7p0 d˝eCc,ltihnee rweahcitciohn mhaigdhtte nbdee dduteo to the balance. However,theconversiondecreasedat80˝Candtheselectivitywasinasharpdeclinewhich excessive activation of the catalyst. And with the increase of reaction time, the conversion increased might be due to the excessive activation of the catalyst. And with the increase of reaction time, the while selectivity decreasing. As a whole, the conversion and selectivity were both higher than 90% at conversion increased while selectivity decreasing. As a whole, the conversion and selectivity were 70 °Cb ointh 6h hig;h sepretchiafnic9a0ll%y,a 9t470.4˝%C iann6d h9;9s.p3e%cifi, crealslpy,e9c4ti.4v%elyan. d 99.3%,respectively. 100 100 (b) 90 99 (a) % C atalysts 2016, Conversion/6 7800 ((bcc)) Selectivity/%9978 (c) 10 60 amount was over5 0200 (ma)g. Taking economics and green c9h6emistry into consideration, a low catalyst amount (200 mg) 4w0 as used in further experiments. 95 2 4 Tim6e/h 8 10 2 4 Tim6e/h 8 10 (A) (B) 2.2.3. Effect of Solvent Figure8. Effectoftemperatureandtimeon(A)conversion;and(B)selectivity. (a): 60˝C;(b): 70˝C; Figure 8. Effect of temperature and time on (A) conversion; and (B) selectivity. (a): 60 °C; In ordera ntdo( ci)n:v80es˝Cti.gate the general application of the synthetic catalyst in different solvents, the (b): 70 °C; and (c): 80 °C. influences of solvents on the oxidation of cyclooctene were studied and the results were summarized in 2.2.2. EffectofCatalystDosage Table 4. Acetonitrile, methanol, ethanol, chloroform, 1,2-dichloroethane, and ethyl acetate were used as 2.2.2. Effect of Catalyst Dosage solvents. TThhee irneflsuuletnsc edseomfodnifsfterraetnetdc athtaalty stthaem sooulnvtesnwtse rweeinrev egsteignaetreadl arnedlevthaentr etsou ltaslkweenreess heopwonxiidnation, Figure 9. It was indicated that the conversion increased with the increase of catalyst amount, but espeTchiael lyin ffolure ancceetso noift ridleif,f emreentht acnaotla, lyasntd acmholournotfso rwme.r eIn inpvaertsitciuglaatre,d thaen dc atthaely triecs urletasc twioenr ew sahso wmno rein furtherimprovedslightlywhentheamountwasover300mg. Theselectivityhadalmostnochange suFiitgaubrlee 9i.n I tt hwea sp ionldairc astoeldv ethnat.t tDheu ec otnov ethrsei ohni ginhc rbeoaisleindg w pitohi ntht ea inndc rsetaasbel eo fs cealetacltyivsti taym oofu ntht,e b uptr ofduurtchte, r whentheamountwasover200mg. Takingeconomicsandgreenchemistryintoconsideration,alow aicmetpornocivatrteiadlley sswltiaagmsh,t oltyhu unwts,(h 2ce0hn0o mtshegen) awamsa sothuuens ert dewaicnatsif ouonrvt hemerr e3de0xiu0pm emr iimgn. e oTnuthsre. e sxepleercitmiveintyt. had almost no change when the 100 100 (d) (b) 90 (c) 99 (d) %80 % (c) Conversion/567000 ((ba)) Selectivity/9978 (a) 40 96 30 20 95 2 4 Tim6e/h 8 10 2 4 Tim6e/h 8 10 (A) (B) Figure9. Effectoftemperatureandtimeon(A)conversionand(B)selectivity. (a): 0.01g;(b):0.02g; Figure 9. Effect of temperature and time on (A) conversion and (B) selectivity. (a): 0.01g; (c):0.03g;(d):0.04g. (b):0.02g; (c): 0.03g; (d): 0.04g. Table 4. Effect of solvents on epoxidation of cyclooctene. Boiling Point Conversion Selectivity Entry Solvent (°C) 4 h 8 h 4 h 8 h 1 Acetonitrile 81.6 88.8 99.4 99.4 99.2 2 Methanol 64.5 92.9 96.8 99.1 96.6 3 Ethanol 78.2 52.0 77.1 98.8 98.8 4 Chloroform 61.2 98.9 100.0 98.6 96.6 5 1,2-Dichloroethane 83.5 8.8 15.0 94.0 93.6 6 Ethyl acetate 78.3 4.5 5.5 85.8 88.2 Reaction conditions: cyclooctene: 2 mmol, solvent: 5 mL, H O : 6 mmol, catalysts: 0.02 g, temperature: 70 °C. 2 2 3. Experimental Section 3.1. Materials and Methods N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol and 3-aminopropyl-trimethoxysilane (APTES) were purchased from Meryer (Meryer, Shanghai, China). Other commercially-available chemicals were bought from local suppliers (Sinopharm Chemical Reagent, Beijing, China). All reagents were purified by standard procedures before use. FT-IR spectra were obtained as potassium bromide pellets in a Catalysts2016,6,2 9of13 2.2.3. EffectofSolvent Inordertoinvestigatethegeneralapplicationofthesyntheticcatalystindifferentsolvents,the influencesofsolventsontheoxidationofcyclooctenewerestudiedandtheresultsweresummarized in Table 4. Acetonitrile, methanol, ethanol, chloroform, 1,2-dichloroethane, and ethyl acetate were used as solvents. The results demonstrated that the solvents were general relevant to alkenes epoxidation,especiallyforacetonitrile,methanol,andchloroform. Inparticular,thecatalyticreaction was more suitable in the polar solvent. Due to the high boiling point and stable selectivity of the product,acetonitrilewas,thus,chosenasthereactionmediuminourexperiment. Table4.Effectofsolventsonepoxidationofcyclooctene. Conversion Selectivity Entry Solvent BoilingPoint(˝C) 4h 8h 4h 8h 1 Acetonitrile 81.6 88.8 99.4 99.4 99.2 2 Methanol 64.5 92.9 96.8 99.1 96.6 3 Ethanol 78.2 52.0 77.1 98.8 98.8 4 Chloroform 61.2 98.9 100.0 98.6 96.6 5 1,2-Dichloroethane 83.5 8.8 15.0 94.0 93.6 6 Ethylacetate 78.3 4.5 5.5 85.8 88.2 Reactionconditions:cyclooctene:2mmol,solvent:5mL,H2O2:6mmol,catalysts:0.02g,temperature:70˝C. 3. ExperimentalSection 3.1. MaterialsandMethods N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol and 3-aminopropyl-trimethoxysilane (APTES) were purchased from Meryer (Meryer, Shanghai, China). Other commercially-available chemicals were bought from local suppliers (Sinopharm Chemical Reagent, Beijing, China). All reagents were purified by standard procedures before use. FT-IR spectra were obtained as potassium bromide pellets in a Nicolet 360 FT-IR thermoscientific spectrometer in the 4000–400 cm´1 region (Thermo Fisher Scientific, Waltham, MA, USA). The elemental analyses were performed on a CHN elemental analyzer (Elementar, Hanau, HE, Germany). TG analysis was carried out with a STA409 instrument in dry air at a heating rate of 10 ˝C¨min´1 (Mettler Toledo, Zurich, Switzerland). SEM image was performed on a HITACHI S-4800 field-emission scanning electron microscope (Hitachi, Tokyo, Japan). Transmission electron microscopic (TEM) photographs of the prepared samples were taken in JEOL JEM 2100 electron microscope under an accelerating voltage of 200 kV (JEOL, Tokyo, Japan). The metal loading of the host materials of Tungsten were determined by inductively-coupled plasma atomic emission spectroscopy (ICP-AES) on a Perkin-Elmer AA-300 spectrophotometer (Shimadzu, Kyoto, Japan). Nitrogen adsorption/desorption isotherms were measured at ´196 ˝C using a Quantachrome Quadrasorb SI automated gas sorption system (Micromeritics instrument corp, Atlanta, GA, USA). Samples were degassed under vacuum for 5 h at 120 ˝C. The micropore volume was obtained with the t-plot method, while the Brunauer-Emmet-Teller (BET) method was applied to calculate the specific surface area. Pore size distributions were evaluated from desorption branches of nitrogen isotherms using the BJH model. The total pore volume was determined at P/P 0.95. The X-ray diffraction (XRD) pattern of 0 the material was recorded on a Bruker D8 advanced powder X-ray diffractometer using Cu Ka (k=1.5406Å)astheradiationsourcein2θrangeof4˝–70˝ withastepsizeof4˝ andasteptimeof 1s(BrukerAxsGmbh,Karlsruhe,BW,Germany). DLSexperimentswerecarriedoutwithprevious sonicationofthesamples. Theruntimeofthemeasurementswas10s. Everysizedistributioncurve was obtained by averaging six measurements. The apparatus was an ALV/DLS/SLS-5022F light scatteringelectronicspectrometer(ALV-GmbH,Langen,Germany). Catalysts 2016, 6 11 Nicolet 360 FT-IR thermoscientific spectrometer in the 4000–400 cm−1 region (Thermo Fisher Scientific, Waltham, MA, USA). The elemental analyses were performed on a CHN elemental analyzer (Elementar, Hanau, HE, Germany). TG analysis was carried out with a STA409 instrument in dry air at a heating rate of 10 °C·min−1 (Mettler Toledo, Zurich, Switzerland). SEM image was performed on a HITACHI S-4800 field-emission scanning electron microscope (Hitachi, Tokyo, Japan). Transmission electron microscopic (TEM) photographs of the prepared samples were taken in JEOL JEM 2100 electron microscope under an accelerating voltage of 200 kV (JEOL, Tokyo, Japan). The metal loading of the host materials of Tungsten were determined by inductively-coupled plasma atomic emission spectroscopy (ICP-AES) on a Perkin-Elmer AA-300 spectrophotometer (Shimadzu, Kyoto, Japan). Nitrogen adsorption/desorption isotherms were measured at −196 °C using a Quantachrome Quadrasorb SI automated gas sorption system (Micromeritics instrument corp, Atlanta, GA, USA). Samples were degassed under vacuum for 5 h at 120 °C. The micropore volume was obtained with the t-plot method, while the Brunauer-Emmet-Teller (BET) method was applied to calculate the specific surface area. Pore size distributions were evaluated from desorption branches of nitrogen isotherms using the BJH model. The total pore volume was determined at P/P 0.95. The X-ray diffraction (XRD) pattern of the material 0 was recorded on a Bruker D8 advanced powder X-ray diffractometer using Cu Ka (k = 1.5406 Å) as the radiation source in 2θ range of 4°–70° with a step size of 4° and a step time of 1s (Bruker Axs Gmbh, Karlsruhe, BW, Germany). DLS experiments were carried out with previous sonication of the samples. The run time of the measurements was 10 s. Every size distribution curve was obtained by averaging six measurements. The apparatus was an ALV/DLS/SLS-5022F light scattering electronic spectrometer (ALV-GmbH, Langen, Germany). Catalysts2016,6,2 10of13 3.2. Catalyst Preparation 3.2. CatalystPreparation Silica nanoparticles, as well as the surface functionalization of the silica nanoparticles with Silica nanoparticles, as well as the surface functionalization of the silica nanoparticles with N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol and APTES, were prepared according to literature with N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol and APTES, were prepared according to literature minowr imthomdiinfiocramtioond i[fi2c7a]t.i oTnh[e2 7ty].pTichaelt pypreicpaalrpatrieopna rpartoiocnedpurorece odfu trheeo cfathtaelycastta wlyasst wina sSicnhSecmhee m1.e 1. N Cl N OH OSi N N OSOi OHOH OSi Cl OSOi OH O O OH Anhydrous toluene, reflux OOSi N N OH OOSi Cl Anhydrous toluene, reflux OH Catalysts 20O1HO6H, 6 OOSi N N OH OOSi Cl 12 (A) (B) N N OSOi NN OSOi Cl OOOSiOOSi N NCl SOiO OSOiCl OOOSi Cl OOSi N N OOSi Cl 1) Anhydrous toluene, 80℃ OH NN 2) H3PW12O40 OOSi N N OOSi Cl OSiO SOiO NCNl HO HO OSOi OOSi CNlN SOiO (C) ScheSmcheem 1e.1 .TTyyppiciaclapl reppraeraptaiornatpiroonce dpurroecoefdthuereca taolfy sttshPeW (cxa)/taSliyOs2tIsm +PCWl´(Sxi)O/S2.iO(A)SIymnt+hCesli−s oSfiO . 2 2 SiO -Im;(B)SynthesisofSiO -Cl;(C)SynthesisofPW(x)/SiO Im+Cl´SiO . 2 2 2 2 (A) Synthesis of SiO -Im; (B) Synthesis of SiO -Cl; (C) Synthesis of PW(x)/SiO Im+Cl− SiO . 2 2 2 2 3.2.1. SynthesisofSilicaNanoparticles 3.2.1. Synthesis of Silica Nanoparticles 74µLammoniasolution(25%–28%)and1.98g(110mmol)waterwereaddedto100mLabsolute methanolina250mLroundbottomflask. Thesolutionwasstirredfor5minbeforeaddingdropwise 74 μL ammonia solution (25%–28%) and 1.98 g (110 mmol) water were added to 100 mL absolute 10.41 g (500 mmol) TEOS. The final solution was stirred for three days at ambient temperature. methanol in a 250 mL round bottom flask. The solution was stirred for 5 min before adding dropwise The resulting solid was centrifuged and washed with methanol and water several times, and dried 10.41u ngd (e5r0v0a cumummo.l) TEOS. The final solution was stirred for three days at ambient temperature. The resulting solid was centrifuged and washed with methanol and water several times, and dried 3.2.2. SynthesisofModifiedSilicaNanoparticles under vacuum. 0.6 g (0.01 mol) previously prepared silica nanoparticle was dispersed in 50 mL anhydrous toluenebysonicationfor60min. Then0.005molN-(3-triethoxysilylpropyl)-4,5-dihydroimidazol(or 3.2.2. Synthesis of Modified Silica Nanoparticles APTES) was added dropwise. The solution was stirred under 110 ˝C for 24 h. The product was filtered, washed in a Soxhlet apparatus with diethyl ether and dichloromethane for 24 h, and then 0.6d rgi e(d0.a0t15 0m˝Colu) npdreervvioaucusluym p.rTehpearoebdta sinileidcap onwandoeprawratiscnlea mweads adsiSsipOer-sIemd ainnd 5S0i Om-LC la,nrehsypdercotiuvse ltyo.luene 2 2 by sonication for 60 min. Then 0.005 mol N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol (or APTES) 3.2.3. SynthesisofSilicaNanoparticleNetwork was added dropwise. The solution was stirred under 110 °C for 24 h. The product was filtered, washed The synthesis was driven by a nucleophilic substitution occurring between an imidazoline in a Soxhlet apparatus with diethyl ether and dichloromethane for 24 h, and then dried at 50 °C under functional group and a chloroalkyl group present on the surface of the silica nanoparticles. vacuum. The obtained powder was named as SiO -Im and SiO -Cl, respectively. 0.5 g silica nanoparticles modified with N-(3-t2riethoxysilylpr2opyl)-4,5-dihydroimidazol and 0.5 g silica nanoparticles modified with APTES were introduced into a 100 mL round bottom flask with 3.2.3.5 S0ymntLheasnihs yodfr oSuilsictao lNueanneo.paTrhtieclseo lNuteiotwnowrka s stirred over 2 days at 70 ˝C and filtered, washed, The synthesis was driven by a nucleophilic substitution occurring between an imidazoline functional group and a chloroalkyl group present on the surface of the silica nanoparticles. 0.5 g silica nanoparticles modified with N-(3-triethoxysilylpropyl)-4,5-dihydroimidazol and 0.5 g silica nanoparticles modified with APTES were introduced into a 100 mL round bottom flask with 50 mL anhydrous toluene. The solution was stirred over 2 days at 70 °C and filtered, washed, finally dried under vacuum. A pale yellow powder was obtained and labelled as SiO Im+Cl− SiO . Elemental analysis: found C: 7.25 wt. %, H: 1.45 wt. %, 2 2 N: 1.96 wt. %. 3.2.4. Synthesis of Phosphotungstate-Loaded Silica Nanoparticle Network Catalysts of PW(x)/SiO Im+Cl− SiO with different H PW O loadings on SiO Im+Cl− SiO were 2 2 3 12 40 2 2 prepared by following strategy. 1.0 g silica nanoparticle network was dispersed in 20 mL deionized water and then added dropwise into an aqueous solution (20 mL) with various amount of H PW O 3 12 40