materials Article In Situ Generation of Fluorescent Copper Nanoclusters Embedded in Monolithic Eggshell Membrane: Properties and Applications LuLi,MinHuang,XianhuLiu,DengmingSunandCongyingShao* CollegeofChemistryandMaterialsScience,HuaibeiNormalUniversity,Huaibei235000,China; [email protected](L.L.);[email protected](M.H.);[email protected](X.L.); [email protected](D.S.) * Correspondence:[email protected];Tel.:+86-561-380-2235 (cid:1)(cid:2)(cid:3)(cid:1)(cid:4)(cid:5)(cid:6)(cid:7)(cid:8)(cid:1) (cid:1)(cid:2)(cid:3)(cid:4)(cid:5)(cid:6)(cid:7) Received:16August2018;Accepted:30September2018;Published:9October2018 Abstract: Luminescentmetalnanoclustershaveattractedconsiderableresearchattentioninrecent yearsduetotheiruniquepropertiesandextensiveusageinmanyfields. Threedifferentsynthetic routesweredevelopedtoinsitugenerateorangeandredemittingcoppernanoclustersembedded in monolithic eggshell membrane (Cu NCs@ESM) using different reducing reagents including N H ·H O, NH OH·HCl and Vitamin C at room temperature for the first time. The routes are 2 4 2 2 extremely facile, low-cost and versatile. The obtained Cu NCs@ESM nanocomposites exhibit excellentphotostabilityandchemicalstability,layingthefoundationforvariouspracticalapplications. Fluorescentsurfacepatterningwasdemonstratedbasedontheproposedstrategyeasily. Significantly, theCuNCs@ESMshowsselectivefluorescencequenchingresponsetoHg2+ionsandgoodcatalytic activityformethyleneblue(MB)reductiondegradationmakingitidealasportablesensingstrip andrecyclablecatalyst. Theworkprovidesageneralstrategyforthefabricationofothervarious monolithicnanomaterialswithpotentialapplications. Keywords: coppernanoclusters;fluorescence;eggshellmembrane;monolithic;applications 1. Introduction Metalnanoclusters(NCs)consistingofseveraltotensofatomshavedrawnconsiderableresearch interestduetotheirlowtoxicity,goodbiocompatibility,multifunctionalsurfacechemistry,andexcellent fluorescencebehaviorssuchasemittingtunability,largeStokesshift,andphotostability[1–4].TheNCs havebeenwildlyappliedinbioimaging[5–7],sensing[8–10],catalysis[11–14],nanodevices[15–17]and manyotherfields[18,19]. However,todate,extensiveresearchonfluorescentmetalnanoclustershas mainlyfocusedonthenoblemetalnanoclusters(especiallyAuandAgNCs). ThestudiesontinyCu NCsarestilldeficientowingtotheirinherentinstability[17,20].Thelessuseofnoblemetalshasattracted everincreasingattentionduetotheirscarcenaturalresourcesandhighcost.Researchersturnedtothe studiesofthefirsttransitionmetalssuchasCu,Fe,Ni,whichcanberegardedasalternativestoAuand Ag. Copperisfrequentlyusedinindustrybecauseofitshighconductivity,similarpropertiestogold andsilverandespeciallymuchlowercost.Therefore,thedevelopmentofvarioussyntheticroutesand extensivepropertiesinvestigationsofCuNCswillbeofgreatpracticalsignificance[21,22]. Recently,manyeffortshaveledtosomeapproachesforCuNCssynthesessuchaspolymerand biomoleculetemplatedmethods[23–31],electrochemicalreduction[32],sonochemicalsynthesis[33], microwave-assisted[34–36]andmicroemulsiontechnology[37,38]. However,thoseas-preparedCu NCsaremostlydispersedinhomogeneoussolution.Agglomeration,precipitationandrecyclingduring practicalapplicationsarethechiefdrawbacksofsolution-dispersedfluorescentCuNCs. Additionally, Materials2018,11,1913;doi:10.3390/ma11101913 www.mdpi.com/journal/materials Materials2018,11,1913 2of16 theseaqueousCuNCsmighthindertheirpotentialapplicationsassolidstatematerialsinchemical sensingstrips,surfacepatterning,light-emittingdevicesandotherfields. However,todate,thereare Materials 2018, 11, x FOR PEER REVIEW 2 of 16 onlyfewreportsonthesynthesesofsolidstateCuNCs. Zhangetal. reportedthesynthesisofsolid fluoresAcedndtitCiounaNllyC, sthienses auqpureaomuso Cleuc uNlCars mhyigdhrto hgienldsevr ithaeeirm ppoltoenytiinalg aappsleicraietisonosf absi lseolaidc isdtadtee mriavtaetriivaless as pre-geliant cohresm[3ic9a]l. sQenisnignge sttarilp.sp, sruorpfoacsee dpatthteernfliungo,r elisgchet-netmCitutinNg Pdsevteicmesp alnatde dothbeyr pfioelldys(.t hHyomwienvee)r, itno the date, there are only few reports on the syntheses of solid state Cu NCs. Zhang et al. reported the agarosehydrogel[40]. Veryrecently, compositepolymerfilmsincorporatingluminescentCuNCs synthesis of solid fluorescent Cu NCs in supramolecular hydrogels via employing a series of bile acid werefabricatedinahydrogelbytheprecursorsofpolyvinylpyrrolidoneandpoly(vinylalcohol)by derivatives as pre-gelators [39]. Qing et al. proposed the fluorescent Cu NPs templated by Wangetal.[41]. Inthementionedwork,thesolidCuNCswereallgeneratedbasedonpre-formed poly(thymine) in the agarose hydrogel [40]. Very recently, composite polymer films incorporating orsimultaneouslypolymerizedhydrogelnetwork. Obviously, sometimespoordispersionofNCs luminescent Cu NCs were fabricated in a hydrogel by the precursors of polyvinylpyrrolidone and inhydprooglye(lvwinyolu alldcolheoald) btoy tWhaenpgh eat sael. s[e4g1]r.e Igna tthieo nmmenatikoinnegd iwtdorikffi, tchuel tsotolidf aCbur iNcaCtse wlaerrgee a-lal rgeean,eurantiefdo rm, photo-sbtaasbelde olun mprien-efoscrmenetdfi olrm ssim. Tuhltuans,eoduesvleyl oppoliynmgesroizmede fhaycdilreogaenld neptrwaoctrikc.a Olsbtvriaotuesgliye, ssotomfeatbimriecsa tpeonoro vel solidstdaitsepeCrsuioNn Cosf NisCasv ienr hyyudrrgoegnelt wanodulfda slecainda ttoi nthget apshka.se segregation making it difficult to fabricate Eglagrsghee-allrema,e munbirfoarnme,( EpShMoto),-sgteanbleer allulmyianbeasncednotn feildmisn. dTahiulys, lidfeev,ehlaospibnege nsodmeem foancsilter aatnedd tporabcetiocanle of natures’strgatieftgsiefso tron faabnroicmataet enroivaellp sroelipda srtaattieo Cnu[ 4N2C].s EisS aM v,earyd uorugebnlet -alnady efarswciantaetirn-ign tsaoslku. blebiomembrane Eggshell membrane (ESM), generally abandoned in daily life, has been demonstrated to be one withinterwovenfibrousstructureattachedinsidetheheneggshell,iscomposedofhighlycross-linked of natureʼs gifts for nanomaterial preparation [42]. ESM, a double-layer water-insoluble andcystine-abundantproteins,whichmakeESMagoodreducingagentandstabilizerinnanoscience. biomembrane with interwoven fibrous structure attached inside the hen eggshell, is composed of Importantly,thethree-dimensionalmonolithicstructurecouldserveasanidealplatform,providing highly cross-linked and cystine-abundant proteins, which make ESM a good reducing agent and richsitesandmakingsurethereisuniformloading. Forinstance, previousresearchbyShaoetal. stabilizer in nanoscience. Importantly, the three-dimensional monolithic structure could serve as an demonidsteraalt peldattfohramt,E pSrMoviwdinags rainche sfifitecsi eanndt smoalikdinsgt sauterep thlaetrfeo irsm unfioforrmge lnoeardaintign. gFoAr uinsatnandceA, pgreNvCiosus[ 43]. Also,Dreesveiarrechp obryt eSdhatoh eet faol.r dmeamtioonnstoraftAedg thNaPt EsSbMy wESaMs an[4 e4f]fi.cAiengta sinol,idP rsatamtea pnliaktfporrmop foosr egdentehreatfionrgm Aaut ion of fluoarnedsc eAngt NACusA [g43a].l lAoylson,a Dnoevpia rretpicolretsedim thme ofborilmizaetidonin osf oAligd NEPSsM by[4 E5S].MN [e4v4]e. rAthgealiens, sP,rtaomtahneikb est ofourpkrnoopwosleedd gthee, tfhoerminatsioitnu osfy fnluthoeressicseonft flAuuoArge saclelonyt CnaunNopCarstiecmlesb eimddmeodbiilnizemd oinn osloitlhidi cEESSMM [4h5a].s n’t been rNepeovretrethdelyesest,. toA thded biteisotn oaf lolyu,r tkhneowealesdegeo,f thoex iind asittiuo nsyontfhCesuis (oEf 0fl,u0o.r3e4scVen)t, Cinu NcoCms pemarbiesdodnedto int hat of Agm(Eo0n,o0li.t8h0ic VES)Ma nhdasnA’tu b(eEen0, re1p.5o0rteVd) ymet.a kAedsdirteiolantaelldy, stthued eyasree omf aoixnidaaticohna ollfe Cnug e(E.0, I0n.3t4h Vis), wino rk, comparison to that of Ag (E0, 0.80 V) and Au (E0, 1.50 V) makes related study remain a challenge. In we established several facile routes for the in situ generation of fluorescent Cu NCs embedded this work, we established several facile routes for the in situ generation of fluorescent Cu NCs in solid state ESM (Cu NCs@ESM), employing different reducing agents at room temperature for embedded in solid state ESM (Cu NCs@ESM), employing different reducing agents at room the first time (Scheme 1), and the reaction conditions and properties of obtained Cu NCs@ESM temperature for the first time (Scheme 1), and the reaction conditions and properties of obtained Cu nanocoNmCps@oEsiStMes nwaenroecoinmvpeosstiitgesa twederien indveetsatiilg.aTtehde ionr edteictaaill.a Tnhdeoerxeptiecaril manedn teaxlpsetruimdieenstahl asvtuedsiheso hwanvet hat CuNCsshopwosns tehsast uCnui qNuCess pizoess-easns duncioqmuep soizseit-i oannd-d ceopmepnodseitniotnc-adteapleynsdisenptr coaptaelrytsieiss p[r1o,1p3e,r1ti4e]s. [W1,1it3h,1m4].a ny attractiWveithfe amtuarneys oatftrtahcetiivne sfietuatugreense roaft etdheC iun NsiCtus -ignecnoerrpatoerda tCedu nNaCnos-cioncmorppoosriatete,din nclaundocinogmpmoosinteo,l ith, low coisntc,lucdoinnvge mnioennotlittha,i lloorwin cgo,stg, ocoondvsetnaiebnilti ttya,iloeraisnyg, sgtooorda gsetaabinlidty,t reaansysp sotorrta,gaen adndla trrgaensSptoorkt,e asn-sdh ift, large Stokes-shift, the as-prepared Cu NCs@ESM nanocomposite is expected to exhibit significant theas-preparedCuNCs@ESMnanocompositeisexpectedtoexhibitsignificantcatalyticandsensing performcaatnalcyet.icH aenrde isne,ntshinegir paeprfpolrimcaatniocne.s Hinerveiisnu, athleHirg a2p+psltirciaptisonsesn insi nvigsubaals Hedg2o+ nstrflipuso rseesncseinngc ebaqsueedn ocnh ing fluorescence quenching and catalysis for methylene blue reduction degradation have been andcatalysisformethylenebluereductiondegradationhavebeendemonstrated. demonstrated. SchemSec1h.eSmceh e1m. aStcihcermepartiecs ernetparteisoenntoaftidoinff eorfe ndtifsfyernetnhte tsiycnrtohuettiecs frooruttehse fionrs itthue gienn esritaut iognenoefrafltuioonr eoscf ent copperflnuaonreosccleunstt ecorsppeemr bneadnodceldusitnerms eomnboelditdheicd eing gmsohneolllimthiecm egbgrsahneell( mCuemNbCrasn@e E(CSuM N).Cs@ESM). Materials2018,11,1913 3of16 2. MaterialsandMethods 2.1. ChemicalsandMaterials Coppersulfate(CuSO ,>99%),sodiumhydroxide(NaOH,>96%),sodiumborohydride(NaBH , 4 4 >98%),hydrazinehydrate(N H ·H O,85%),VitaminC(VC,>99.7%),hydroxylaminehydrochloride 2 4 2 (NH OH·HCl),mercurynitrate(Hg(NO ) ),ethanol(99.7%),andmethyleneblue(MB)werepurchased 2 3 2 fromSinopharmChemicalReagentCo.,Ltd(Shanghai,China). Otherchemicalsareallofanalytical grades. Allthereagentswereusedasreceivedwithoutfurtherpurification. Deionizedwaterwitha conductivityof18.2MΩ·cm−1waspurifiedthroughaMilliporewaterpurificationsystemandwas usedthroughtheexperiment. FresheggswerepurchasedfromZhenBangsupermarketneartheHuaiBeiNormalUniversity (Huaibei,China). TheESMswerepeeledofffromthenaturaleggshellsmanuallyandcleanedwith copiousamountofdeionizedwatercarefully. TheresultantESMswerecutintoproperrectangular pieces(about1×1.5cm2)andstoredindeionizedwaterbeforeuse. 2.2. Instruments Fluorescence spectra of Cu NCs@ESMs were recorded with a FP-8300 spectrophotometer equippedwithsolidsampleholder(Jasco,Tokyo,Japan). Thephotosofallsamplesweretakenwith aMeiZumobilephone(Zhuhai,China). Thefluorescentphotosunder365nmUVlightweretaken underaZF-20Dblack-box-styleUVbasedanalyzer(YuHua,GongYi,China). Surfacemorphology of fluorescent Cu NCs@ESMs were observed under an Olympus IX71 fluorescence microscope (Tokyo, Japan). The X-ray photoelectron spectra (XPS) were obtained on an ULVAC-PHI X-ray photoelectron spectrometer (PHI Quantera, Tokyo, Japan) using Al Kα radiation. Quantitative analyses of the copper contents in Cu NCs@ESMs were performed on Perkin Elmer Opyima 7300ICP-AES(Waltham,MA,USA). TheUV-visabsorptionspectraanddiffusereflectancespectra (DRS) measurements were carried out using a PGENERAL TU-1901 UV-vis spectrophotometer (PurkinjeGeneralInstrument,Beijing,China). Thetime-resolvedfluorescencedecaywasinvestigated by time correlated single photon counting (TCSPC) technique on FLS 920 (Edinburgh Instrument, Edinburgh,UK). 2.3. SynthesisofCuNCs@ESMUsingN H ·H O 2 4 2 AcleanedpieceofESMplatformwasincubatedinanaqueousofCuSO solution(1mL,50mM) 4 for10min. Then,excessiveCuSO wasremoved,andtheCu2+impregnatedESM(Cu2+/ESM)was 4 transferred into 1 mL N H solution (85%) to initialize the reduction. The process typically took 2 4 approximately5~7hatambienttemperaturetogetstronglyorangeemittingCuNCs@ESM. 2.4. SynthesisofCuNCs@ESMUsingNH OH·HClorVC 2 In a typical process, a piece of ESM was incubated in a solution of CuSO (1 mL, 50 mM) for 4 10min. Afterthat,theobtainedCu2+/ESMwastreatedwithNaOHsolution(1mL,10M)for20min, andthentransferredinto1mL1MNH OH·HClor2MVCsolution,immediately. Thereactiontook 2 5htogenerateintenseredfluorescentCuNCs@ESMatambienttemperature. 2.5. SurfacePatterningonESMSubstrate Firstly,“Cu-N-C-s”lettersorthepatternofsmilingfacewerewrittendirectlyonanESMsubstrate with50mMCuSO solutionas“ink”. Then, theESMwiththeimpregnatedlettersorpatternwas 4 soakedinto10MNaOHsolutionfor20min. Finally,thetreatedESMwastransferredinto2MVC solutionfor5h,andthefluorescentlettersorpatternwerefabricatedembeddedintheESMsubstrate. Materials2018,11,1913 4of16 2.6. ResponseofCuNCs@ESMStripstoHg2+Ions Inatypicalprocedure,theas-preparedmonolithicCuNCs@ESMwascutintosmallpieces. Then, thesmallpieceswereaddedinto1mLHg(NO ) solutionwithdifferentconcentrationsandincubated 3 2 atambienttemperature. Afterthat,thefluorescencewasobservedunder365nmUVlight. Meanwhile, theinfluenceofotherinterferenceswasalsoinvestigatedwiththeconcentrationsof500µM. 2.7. CatalyticActivityofCuNCs@ESMforMBReduction Typically,theas-preparedCuNCs@ESMnanocompositewasbrieflythrowninto1mL30µM methyleneblue(MB)solutioninthesunlight. ThecatalyticdegradationofMBdyeinthepresenceof CuNCs@ESMwasmonitoredbytheUV-visspectrometer. 3. ResultsandDiscussion 3.1. SynthesisandCharacterizationofCuNCs@ESMUsingN H ·H O 2 4 2 PreviousresearchdemonstratedtheformationofnobleAuandAgNCsbasedonthereductive ability of ESM itself in alkaline solution [43,45,46]. What about the in situ synthesis of Cu NCs employingESMasthesolidstateplatform? Herein,ininitialexperimentstheESMsweretreatedby thesesimilarwayswithcuriosity[43](FiguresS1–S3). TheresultsshowthecolorofESMsincubated with Cu2+ rapidly changed from blue to purplish red in alkaline solution, as described in other literatures[20,47],whichindicatedtheformationofCu-ESMcomplex. However,nofluorescentCu NCs were further formed, even if the reaction was prolonged to several days or the reaction was allowedtoproceedatelevatedtemperature(55◦C)employingESMitselfasthereducerinalkaline solution, whichwasgreatlydifferentfromthatofAu-ESMandAg-ESM.Therefore, newdifferent routes would be needed to generate fluorescent Cu NCs embedded in monolithic ESM. We then attemptedtointroduceanexternalreductant,N H ·H O,toinitializethereductionprocess. Typically, 2 4 2 theESMdisplayedabluecoloraftertreatingwithCuSO solutionfor10min,indicatingthatCu2+ 4 wasadsorbedontoESMduetothecoordinationbetweenCu2+ andthefunctionalgroups(amines, amides, and carboxylic groups) of the ESM fibers [47]. Exhilaratingly, after the introduction of N H ·H O,theabsorbedCu2+couldbereducedtoCu(0)andthusinducedsimultaneousnucleation 2 4 2 andsize-regulatinggrowthoffluorescentCuNCsembeddedinESMplatform. Figure1ashowsthe obtainedCuNCs@ESMhadayellowishcolorunderroomlightcharacteristicofultrafineCuNCs andemittedintenseorangefluorescencecenteredat602nmexcitedwith365nmUVlight(Figure1b). SeparatecontrolexperimentsweresimultaneouslyperformedbytreatingESMswithN H ·H Oand 2 4 2 CuSO ,respectively,andnoorangefluorescencewasobserved. Additionally,theinsitugeneratedCu 4 NCsshowedanexcitationmaximumat317nm(FigureS4).Besides,theexcitationdependenceproperty ofCuNCsembeddedinESMwasalsoinvestigated,andnoobviousexcitation-dependentbehavior wasobservedwhentheexcitationwavelengthschangedfrom260to420nm,indicatingthatthesize distribution of in situ generated Cu NCs is equally uniform (Figure 1c). Fluorescence microscope images (Figure 1a) show the characteristic interwoven fibrous structure of ESM remained almost unchangedafterthesurfaceandinsideloadingoforangeemittingCuNCs,whencomparedwiththe naturalblueemittingESMsubstrate. Itisnoteworthythatthebluefluorescencewasdramatically suppressedaftertheinsitugenerationofCuNCscomparedwiththeESMitself(insetinFigure1b). OnepossiblereasonwasthattheoxidationandreductionofsomecomponentsinthenaturalESM substrateoccurredduringthereactionprocess. Ontheotherhand,theenergytransferbetweenthe blueemissionfromESMitselfandtheclustersorotherproductswasnotunexpectedwhenexited withthe365nmUVlight[43]. ThecontentofcopperinmonolithicCuNCs@ESMwasdetermined to be 1.2% by inductively coupled plasma atomic emission spectroscopy (ICP-AES). XPS analysis also verified the existence of Cu(0) on the ESM, which showed two strong peaks at 932.2 eV and 952.2 eV in the spectrum, corresponding to the Cu2p and Cu2p of Cu(0), respectively. The 3/2 1/2 absenceofCu2p3/2satellitepeakaround942eVindicatedtheabsenceofCu(II)inthepreparedCu Materials2018,11,1913 5of16 Materials 2018, 11, x FOR PEER REVIEW 5 of 16 tNheC sp@reEpSaMre(dF iCguu rNe1Cds)@.EASsMw e(Fkignuorwe, 1thde).2 Aps3/ w2be iknndoinwg, etnheer g2py3o/2f bCinud(0in)gis eonnelyrg~y0 o.1f eCVua(0w) aisy ofrnolmy ~t0h.a1t eoVf Cawu(aI)ys fproecmie tsh.aTth oefr Cefuo(rIe), stpheecvieasle. nTcheersetafotereo,f ththee vCaulenincep srotatteein ofm thater iCxum ino sptrloikteeilny mlieastrbiext wmeoesnt l0ikaenlyd +li1es[ 1b3e,t2w0]e.en 0 and +1 [13,20]. Figure1.CharacterizationofESMsembeddedwithorwithoutCuNCs.(a)Roomlight(upperpanel) Figure 1. Characterization of ESMs embedded with or without CuNCs. (a) Room light (upper panel) and UV light (lower panel) photos of Cu NCs@ESM and controls. Samples from left to right and UV light (lower panel) photos of Cu NCs@ESM and controls. Samples from left to right correspond to ESM in H O, ESM in N H ·H O, ESM in CuSO , and Cu NCs@ESM, respectively. correspond to ESM in H2O2, ESM in N2H24·H42O,2 ESM in CuSO4, an4d Cu NCs@ESM, respectively. The ThefluorescencemicroscopyimageofESM(middle)andas-obtainedCuNCs@ESM(right)excited fluorescence microscopy image of ESM (middle) and as-obtained Cu NCs@ESM (right) excited by 365 by365nm;(b)Fluorescenceemissionspectraof1–4samplesexcitedby365nm. Inset:fluorescence nm; (b) Fluorescence emission spectra of 1–4 samples excited by 365 nm. Inset: fluorescence spectra spectraofESMitselfbeforeandafterloadingCuNCsinthebluelightregion;(c)Fluorescenceemission of ESM itself before and after loading Cu NCs in the blue light region; (c) Fluorescence emission spectraofCuNCs@ESMwithvaryingexcitationwavelengthsfrom260to420nm;(d)XPSspectraof spectra of Cu NCs@ESM with varying excitation wavelengths from 260 to 420 nm; (d) XPS spectra of theCuNCs@ESMandESMintheCu2pregion. the Cu NCs@ESM and ESM in the Cu 2p region. In the synthetic route, the concentrations of CuSO precursor and N H ·H O reducer 4 2 4 2 In the synthetic route, the concentrations of CuSO4 precursor and N2H4·H2O reducer played played crucial roles in generating fluorescent Cu NCs. Additional experiments were performed crucial roles in generating fluorescent Cu NCs. Additional experiments were performed (Figures S5 (FiguresS5andS6) and the results show more than 5 mM Cu2+ and 85% N H ·H O solution 2 4 2 and S6) and the results show more than 5 mM Cu2+ and 85% N2H4·H2O solution (~17 M) were effective (~17M)wereeffectivetoformstronglyorangeemittingCuNCsembeddedinESMafterthereaction to form strongly orange emitting Cu NCs embedded in ESM after the reaction duration of 5 h at room durationof5hatroomtemperature. Interestingly,whenthepreparedmonolithicCuNCs@ESMwas temperature. Interestingly, when the prepared monolithic Cu NCs@ESM was always immersed in alwaysimmersedinN H ·H Oreactionsolutionuntilseveraldaysat4◦C,themembranegradually 2 4 2 N2H4·H2O reaction solution until several days at 4 °C, the membrane gradually dissolved due to the dissolved due to the alkaline hydrolysis and a homogeneous solution with brownish yellow was alkaline hydrolysis and a homogeneous solution with brownish yellow was obtained, suggesting the obtained,suggestingtheimmobilizedCuNCswerereleasedintoaqueoussolutionanddispersed immobilized Cu NCs were released into aqueous solution and dispersed homogeneously. The homogeneously. Themaximumexcitationandemissionpeakswereobservedat337nmand606nm, maximum excitation and emission peaks were observed at 337 nm and 606 nm, and the aqueous Cu andtheaqueousCuNCswasexcitation-independentastheparentCuNCs@ESM(FigureS7).Thelarge NCs was excitation-independent as the parent Cu NCs@ESM (Figure S7). The large Stokes shift up to Stokesshiftupto269nmoftheCuNCsmakesitactuallyapplicablewithverylowbackgroundand 269 nm of the Cu NCs makes it actually applicable with very low background and light scattering lightscatteringinterference,whichisidealforbioimagingandbiosensing. interference, which is ideal for bioimaging and biosensing. 3.2. SynthesisandCharacterizationofCuNCs@ESMUsingNH OH·HCl 2 3.2. Synthesis and Characterization of Cu NCs@ESM Using NH2OH·HCl Intheabovecase,thefluorescentCuNCsweresuccessfullyinsitugeneratedinESMbyexternally In the above case, the fluorescent Cu NCs were successfully in situ generated in ESM by introducedN H ·H Oasthereducer. Inordertodevelopdiversesyntheticroutes,otherreducing 2 4 2 eaxgteenrntsa,lNlya iBnHtrodanudceNd HN2OHH4·H·H2OCl aws etrheea rlesodutrcieerd. tIon porredpearr teofl dueovreelsocpen dtiCvuerNseC ssy@nEthSeMtice mropultoeysi, nogththere 4 2 rseimduilcainrgsy angthenettisc, rNouaBteH.4H aonwde vNeHr,2vOeHry·HwCela kwlyerree dalesom ittrtiiendg tCou pNreCpsarceo uflludobreesocbetnati nCeud vNiaCsN@aEBSHM 4 employing the similar synthetic route. However, very weakly red emitting Cu NCs could be obtained reduction. Inparticular,thereactionconditionwasrelativelyharsh,anditseemedverydifficultto via NaBH4 reduction. In particular, the reaction condition was relatively harsh, and it seemed very difficult to control a good nucleation and growth of copper clusters due to the strong reducing Materials2018,11,1913 6of16 Materials 2018, 11, x FOR PEER REVIEW 6 of 16 control a good nucleation and growth of copper clusters due to the strong reducing capacity and capacity and instability of NaBH4 itself (Figure S8). Meanwhile, no fluorescent CuNCs could be instability of NaBH4 itself (Figure S8). Meanwhile, no fluorescent CuNCs could be generated by generated by NH2OH·HCl reduction in the case. One possible reason is that, comparable to NaBH4 NH OH·HClreductioninthecase. Onepossiblereasonisthat,comparabletoNaBH andN H ·H O, and2 N2H4·H2O, the lower reducibility of NH2OH·HCl was uncapable of convertin4g Cu(II2) to4 Cu2(0) thelowerreducibilityofNH OH·HClwasuncapableofconvertingCu(II)toCu(0)effectively. effectively. 2 Intriguingly,itwasfoundthattheCu2+/ESMtreatedsubsequentlywithstrongalkalinesolution Intriguingly, it was found that the Cu2+/ESM treated subsequently with strong alkaline solution before throwing into NH OH·HCl could be reduced to obtain red fluorescent Cu NCs effectively. before throwing into NH22OH·HCl could be reduced to obtain red fluorescent Cu NCs effectively. In Inthetypicalprocedure,ESMwasbrieflyincubatedinaCuSO solution(1mL,50mM)for10min, the typical procedure, ESM was briefly incubated in a CuSO4 so4lution (1 mL, 50 mΜ) for 10 min, and andthentheESMimmobilizedwithCu2+wassoakedinaNaOHsolutionof10Mfor30minduring then the ESM immobilized with Cu2+ was soaked in a NaOH solution of 10 M for 30 min during which whichthemembranecolorchangedtopurplishredfromblueindicatingtheformationofESM-Cu the membrane color changed to purplish red from blue indicating the formation of ESM-Cu complex complex[20,47],andfinallytransferredinto1MNH OH·HCltoinitiatethereduction. Asthereaction [20,47], and finally transferred into 1 M NH2OH2·HCl to initiate the reduction. As the reaction proceededfor1h,thecolorofthemembranechangedfrompurplishredtoyellow,suggestingthe proceeded for 1 h, the color of the membrane changed from purplish red to yellow, suggesting the formation of Cu NCs embedded in ESM. Figure 2a shows the images of obtained Cu NCs@ESM formation of Cu NCs embedded in ESM. Figure 2a shows the images of obtained Cu NCs@ESM by by NH OH·HCl reduction under alkaline environment. The Cu NCs@ESM emitted obvious red NH2OH2·HCl reduction under alkaline environment. The Cu NCs@ESM emitted obvious red fluorescence peaked at 652 nm (Figure 2b), and the maximum excitation was 370 nm (Figure S9). fluorescence peaked at 652 nm (Figure 2b), and the maximum excitation was 370 nm (Figure S9). The ThegeneratedCuNCsembeddedinmonolithicESMhaveexcitation-independentproperty(Figure2c) generated Cu NCs embedded in monolithic ESM have excitation-independent property (Figure 2c) suggestingtheuniformsizeandnarrowdistributionofCuNCs. XPSanalysisfurtherrevealedthe suggesting the uniform size and narrow distribution of Cu NCs. XPS analysis further revealed the existenceofCu(0)embeddedinESM(Figure2d),andthetotalcoppercontentwasdeterminedtobe existence of Cu(0) embedded in ESM (Figure 2d), and the total copper content was determined to be 2.4%byICP-AES. 2.4% by ICP-AES. Figure2. PhotosandspectraofCuNCs@ESMbyNH OH·HClreductionunderalkalinecondition. Figure 2. Photos and spectra of Cu NCs@ESM by NH2O2H·HCl reduction under alkaline condition. (a) (a)PhotosofCuNCs@ESMunderroomlight(left)and365nmUVlight(middle)alongwiththe Photos of Cu NCs@ESM under room light (left) and 365 nm UV light (middle) along with the fluorescencemicroscopyimage(right);(b)FluorescenceemissionspectraofCuNCs@ESMandESM fluorescence microscopy image (right); (b) Fluorescence emission spectra of Cu NCs@ESM and ESM excitedby365nm;(c)FluorescencespectraofCuNCs@ESMwithvaryingexcitationwavelengthsfrom excited by 365 nm; (c) Fluorescence spectra of Cu NCs@ESM with varying excitation wavelengths 300to560nm;(d)XPSspectrumofCuNCs@ESMintheCu2pregion. from 300 to 560 nm; (d) XPS spectrum of Cu NCs@ESM in the Cu 2p region. As shown in Figure S10, weakly red emitting Cu NCs were generated after reaction in As shown in Figure S10, weakly red emitting Cu NCs were generated after reaction in NH OH·HClsolutionsfor1~6h,whentheCu2+/ESMsweretreatedsubsequentlywith500mM~5M NNaHO22HOHa·qHuCelo suoslustoiolunsti ofonr 1b~e6f ohr,e wthherno wthine gCuin2+t/oES1MsM weNreH trOeaHte·dH Csul,bsreeqsupeencttliyv ewlyi.th 5E0v0e mnMm~o5r Me, NaOH aqueous solution before throwing into 1 M NH2O2 H·HCl, respectively. Even more, no no fluorescence was observed during the whole reaction with a NaOH concentration lower than fluorescence was observed during the whole reaction with a NaOH concentration lower than 500 500 mM. However, when the concentrations of NaOH solution reached 10~12 M, the visible red mM. However, when the concentrations of NaOH solution reached 10~12 M, the visible red emitting emittingCuNCscouldbeinsitugeneratedwithin30min,andthefluorescencestrengthreacheda Cu NCs could be in situ generated within 30 min, and the fluorescence strength reached a maximum maximumafter5h. Obviously,intheprocedureemployingNH OH·HClasreductant,thestrong after 5 h. Obviously, in the procedure employing NH2OH·HCl2 as reductant, the strong alkaline alkalineconditionwasessentialforthegenerationofredfluorescentCuNCs. First,inacidandneutral condition was essential for the generation of red fluorescent Cu NCs. First, in acid and neutral aqueous solution, free carboxyl and amino groups in ESM were partly dissociated into negatively Materials2018,11,1913 7of16 aqueoussolution, freecarboxylandaminogroupsinESMwerepartlydissociatedintonegatively chargedspecies,incubatingESMwithCu2+ immediatelyproducedCu2+/ESMassociationbytheir electrostaticattractionandcoordination. Subsequently,theacidityofsolutionwasadjustedtomore thanpH12byaddingNaOHandthisresultedinanincreaseinthedegreeofexposureoffreeamino groupswhichcouldcombinewithCu2+easilytoformastablecomplex.Second,thereducingcapability oftyrosineresiduescanbegreatlyimprovedbyadjustingthereactionpHabovethepKaofTyr(~10). Hence,thereducingcapabilityofESMitselfwasnotunexpectedsinceitcontainsTyrresiduesand possibly other residues with reduction functionality. Third, Kodali et al. reported the presence of considerableamountofcysteine-richESMproteinswithmultipledisulfidecrosslink[48]. Thedisulfide bondscouldbecleavedintofree-SHunderalkalineenvironment. Andthe-SHcaneasilycombine toformstableCu-Sbond,whichcanstabilizethenucleatedclusters. Theinfluencesofotherprocess parameters,suchasincubationtime,theconcentrationsofCuSO precursorandNH OH·HClwere 4 2 alsoinvestigatedsystematically,whichwereshowninFigureS11–S13. 3.3. SynthesisandCharacterizationofCuNCs@ESMUsingVC VCisonemildandenvironmentallyfriendlyreagent,whichwasoftenusedinthenanomaterials preparationinsteadofsomesevereortoxicreductants. Herein,VCwasalsoemployedtogenerate fluorescentCuNCsembeddedinESM.Excitedly,itwasfoundthatVCcouldinsitureduceCu2+loaded onESMintofluorescentCuNCsunderalkalinesolution. TheobtainedCuNCs@ESMhadayellowish color and emitted strong red fluorescence centered at 643 nm under 365 nm UV irradiation with interwovenfibrousstructure(Figure3a,b).TheCuNCs@ESMhadamaximumexcitationat375nmand themaximumemissionwavelengthwasalmostinvariablewhentheexcitationwavelengthschanged from340to570nmindicatingtheuniformsizedistributionofgeneratedNCs(FiguresS14and3c). Itnoteworthythatdifferentorangeandredfluorescencewereobservedinthedevelopedthreesynthetic routes, which was confirmed by the excitation and emission spectra of Cu NCs@ESM composites fabricatedbyemployingdifferentreducingreagents(FiguresS4,S9andS14). Althoughtheexactsize determinationoftheCuNCsembeddedintheESMwasdifficult,thedifferentsizeofclusterscouldbe expectedindifferentsyntheticroutesduetothedifferentclusteringprocessofCuatomsunderdifferent reactionenvironmentandthesize-dependentfluorescencecouldbeachievedbyvaryingthesynthetic routes [17]. The content of copper in the obtained Cu NCs@ESM was determined to be 1.6% by ICP-AES.ThegenerationofCu(0)ontheESMplatformwasfurtherdemonstratedbytheCu2P and 3/2 Cu2P peakscenteredat931.6and951.3eV,respectively(Figure3d). Thetime-resolvedfluorescence 1/2 decayoftheobtainedCuNCs@ESMwassimultaneouslyinvestigatedbytimecorrelatedsinglephoton counting (TCSPC) technique, and the average lifetime of generated Cu NCs was calculated to be 2.84ns(FigureS15). Inthetypicalalkalinecondition,whentheconcentrationsofCuSO precursor 4 wasmorethan10mMandconcentrationsofVCwasmorethan1M,theredfluorescentCuNCswere generatedinafewminutesandreachedthestrongestfluorescenceabout5h(FiguresS16andS17). Ithastobenotedthatthestrongalkalineenvironmentplaysakeyroleinthesyntheticroute. Whenthe ESMwaspre-incubatedin1mLCuSO (50mM)for10min,thentreatedwithNaOHaqueoussolution 4 ofconcentrationslowerthan0.1M,andfinallytransferredto2MVCsolution,nofluorescentCuNCs couldbegeneratedevenwithaprolongedreaction(FigureS18). Thismaybeduetothereducing capabilityofESMitselfandVCwasinitiatedeffectivelyinstrongalkalineconditiontogeneratemetal nucleationandfluorescentclustersasexpected. To test the effect of copper precursors on the fluorescence of Cu NCs@ESM in the developed strategies,variouscopperprecursorssuchasCuCl ,Cu(NO ) ,Cu(CH COO) ,CuSO wereemployed 2 3 2 3 2 4 inthethreeroutesreducedbyN H ·H O,NH OH·HClandVC,respectively. Theresultsshowthat 2 4 2 2 brightlyorangeandredemittingCuNCscouldbegeneratednomatterwhatkindoftheabovefour copper precursors was employed (Figure S19). Interestingly, the ESM platform, even if boiled in water,wasalmostequallyefficientintheproposedmethodsforgeneratingfluorescentCuNCs@ESM (FigureS20). Inaddition,UV-VisDRSmeasurementwasconductedtofurtherconfirmthesuccessful Materials2018,11,1913 8of16 fMoratmeriaatlsi o20n18o, f11C, ux FNOCR sPEoEnR tRhEeVEIESWM substrate[44]. AsshowninFigure4,therewerenocharacter8i osft i1c6 Materials 2018, 11, x FOR PEER REVIEW 8 of 16 surfaceplasmonresonance(SPR)absorptionofCunanoparticles(CuNPs)locatedat~560nminthe spectra of Cu NCs@ESM fabricated by the three different routes, indicating the in situ generation of spectraofCuNCs@ESMfabricatedbythethreedifferentroutes,indicatingtheinsitugenerationof spectra of Cu NCs@ESM fabricated by the three different routes, indicating the in situ generation of ultra-small Cu NCs rather than the large-sized Cu NPs [31]. ultra-smallCuNCsratherthanthelarge-sizedCuNPs[31]. ultra-small Cu NCs rather than the large-sized Cu NPs [31]. Figure 3. Photos and spectra of Cu NCs@ESM by VC reduction under alkaline condition. (a) Photos FFiigguurree 33.. PPhhoottooss aanndd ssppeeccttrraa ooff CCuu NNCCss@@EESSMM bbyy VVCC rreedduuccttiioonn uunnddeerr aallkkaalliinnee ccoonnddiittiioonn.. ((aa)) PPhhoottooss of obtained Cu NCs@ESM under room light (left) and 365 nm UV light (middle) along with the of obtained Cu NCs@ESM under room light (left) and 365 nm UV light (middle) along with the of obtained Cu NCs@ESM under room light (left) and 365 nm UV light (middle) along with the fluorescence microscopy image (right); (b) Fluorescence emission spectra of Cu NCs@ESM and ESM fluorescencemicroscopyimage(right);(b)FluorescenceemissionspectraofCuNCs@ESMandESM fluorescence microscopy image (right); (b) Fluorescence emission spectra of Cu NCs@ESM and ESM excited by 365 nm; (c) Fluorescence spectra of Cu NCs@ESM by varying excitation wavelengths from excitedby365nm;(c)FluorescencespectraofCuNCs@ESMbyvaryingexcitationwavelengthsfrom excited by 365 nm; (c) Fluorescence spectra of Cu NCs@ESM by varying excitation wavelengths from 340 to 570 nm; (d) XPS spectrum in the Cu 2p region of the resulting Cu NCs@ESM. 340to570nm;(d)XPSspectrumintheCu2pregionoftheresultingCuNCs@ESM. 340 to 570 nm; (d) XPS spectrum in the Cu 2p region of the resulting Cu NCs@ESM. 2.4 ESM 2.4 E CSuM NCs@ESM reduced by N2H4 C Cuu N NCCss@@EESSMM r reedduucceedd b byy N N2HH42 OH·HCl C Cuu N NCCss@@EESSMM r reedduucceedd b byy N VHC2OH·HCl 2.0 Cu NCs@ESM reduced by VC 2.0 s 1.6 sb 1.6 bA A 1.2 1.2 0.8 0.8 200 300 400 500 600 700 800 200 300 400 500 600 700 800 Wavelength(nm) Wavelength(nm) FFiigguurree 44.. TThhee UUVV--vviiss DDRRSS ssppeeccttrraa ooff nnaattuurraall EESSMM ((bbllaacckk lliinnee)) aanndd aass--oobbttaaiinneedd CCuu NNCCss@@EESSMM Fnniaagnnuoorcecoo m4m. ppToohssieitt eeUss Viinn- vsisisti utuD gRgeSne nesreparteaectdetrd ab ybo yNf 2nNHa24t·HuHr4a2·OlH E2reOSdMur ce(tdbioulancc tk(ior enldin (leri)en dea)n,l diNn eHa)s,2-OoNHbHt·aH2inOCelHd r ·eHCduCu clNtiroCends @u(gcEtrSieoMenn n(lgianrneeoe)c naonlmidnp eVo)Csain tredesd ViunCc tsriioetudn u (gcbetlniuoeenr la(itnbeledu) ,e brlyeins Npee)2,Hcrtei4v·sHepl2eyOc.t irveedlyu.ction (red line), NH2OH·HCl reduction (green line) and VC reduction (blue line), respectively. It is noteworthy that the blue fluorescence was also dramatically suppressed after the generation It is noteworthy that the blue fluorescence was also dramatically suppressed after the generation of Cu NCs compared with the ESM itself in the NH2OH·HCl and VC reduction routes (Figure S21). oAf cCcuor NdiCnsg ctoom thpea reexdc iwtaittiho nth sep EecStMra iotsf etlhf ei nf atbhrei cNatHed2O cHom·HpCols aitneds (VFCig urerdesu cSt9io ann dro Su1te4s) , (oFnigeu preo sSs2i1b)l.e According to the excitation spectra of the fabricated composites (Figures S9 and S14), one possible reason was that an efficient fluorescence resonance energy transfer (FRET) could happen between the reason was that an efficient fluorescence resonance energy transfer (FRET) could happen between the Materials2018,11,1913 9of16 Itisnoteworthythatthebluefluorescencewasalsodramaticallysuppressedafterthegeneration oMfaCteruialNs 2C01s8c, o11m, xp FaOrRe dPEwERit hREtVhIeEWES MitselfintheNH OH·HClandVCreductionroutes(Figure9S o2f1 1)6. 2 Accordingtotheexcitationspectraofthefabricatedcomposites(FiguresS9andS14),onepossible ESM protein and Cu NCs, indicating a spatial proximity between the formed Cu NCs and the protein reasonwasthatanefficientfluorescenceresonanceenergytransfer(FRET)couldhappenbetween fluorophores inside the ESM, and the excellent stability of the obtained monolithic Cu NCs@ESM the ESM protein and Cu NCs, indicating a spatial proximity between the formed Cu NCs and could be expected. On the other hand, the contribution of the oxidation or reduction of some theproteinfluorophoresinsidetheESM,andtheexcellentstabilityoftheobtainedmonolithicCu components in the natural ESM substrate during the reaction process was not unexpected. As shown NCs@ESM could be expected. On the other hand, the contribution of the oxidation or reduction in Figure S22, the red fluorescence intensity of monolithic Cu NCs@ESM was still strong stored in ofsomecomponentsinthenaturalESMsubstrateduringthereactionprocesswasnotunexpected. wet form (dipped in water) for around 15 days and even more than a month in dried form at 4 °C in AsshowninFigureS22,theredfluorescenceintensityofmonolithicCuNCs@ESMwasstillstrong the refrigerator. Moreover, photobleaching was not observed even when the product had been storedinwetform(dippedinwater)foraround15daysandevenmorethanamonthindriedformat 4co◦nCtiinnutohuesrleyf riirgreardaitaotre.dM uonrdeoevr e3r6,5p hnomto UblVea lcihgihntg fowra 1s2n ho t(oFbigsuerrve eSd23ev).e Antwtrhacetnivtheleyp, rthode uflcutohraedscbeenecne intensity could be maintained without any weakening even under high ionic strength conditions (1 continuouslyirradiatedunder365nmUVlightfor12h(FigureS23). Attractively,thefluorescence M NaCl solution, Figure S24) for a long period of time. In addition, the Cu NCs@ESM remained very intensity could be maintained without any weakening even under high ionic strength conditions stable in the majority of organic solvents while immediate fluorescence quenching occurred in (1MNaClsolution,FigureS24)foralongperiodoftime. Inaddition,theCuNCs@ESMremained ethanol as shown in Figure 5a, and the fluorescence intensity decreased continuously with increasing verystableinthemajorityoforganicsolventswhileimmediatefluorescencequenchingoccurredin evtohlaunmole afsraschtoiownns ionf Feitghuarneo5l a(,vaonl d%t,h eethflaunoorel:sHce2Onc).e Iitn stehnosuitldy dbeec nreoatseedd tchoant tain luoowu svloyluwmithe finraccrteiaosnin ogf 0.05% could result in an obviously distinguishable response from the background quickly (Figure volumefractionsofethanol(vol%,ethanol:H O).Itshouldbenotedthatalowvolumefractionof 2 5b). The effective response of Cu NCs@ESM to ethanol content indicates the promise to develop 0.05%couldresultinanobviouslydistinguishableresponsefromthebackgroundquickly(Figure5b). visual sensing strips for ethanol solution and vapor conveniently based on the monolithic products. TheeffectiveresponseofCuNCs@ESMtoethanolcontentindicatesthepromisetodevelopvisual Herein, the fluorescent stability of Cu NCs embedded in ESM substrate was contributed to the sensingstripsforethanolsolutionandvaporconvenientlybasedonthemonolithicproducts. Herein, protection of fibrous ESM structure and rich functional groups in the natural ESM acting as thefluorescentstabilityofCuNCsembeddedinESMsubstratewascontributedtotheprotectionof nucleation template and capping stabilizer, which avoids the aggregation and oxidation induced fibrousESMstructureandrichfunctionalgroupsinthenaturalESMactingasnucleationtemplateand fluorescence quenching. In the presence of ethanol, ESM substrate was denatured mainly due to the cappingstabilizer,whichavoidstheaggregationandoxidationinducedfluorescencequenching. Inthe destroy of hydrogen bonds and hydrophobicity of the composed proteins, and a looser structure was presenceofethanol,ESMsubstratewasdenaturedmainlyduetothedestroyofhydrogenbondsand expected. Thus, the protection of ESM with Cu NCs was correspondingly weakened and the surface hydrophobicityofthecomposedproteins,andalooserstructurewasexpected. Thus,theprotectionof chemical environment of the clusters exhibited a significant change, resulting in easy oxidation of Cu ESMwithCuNCswascorrespondinglyweakenedandthesurfacechemicalenvironmentoftheclusters NCs and fluorescence quenching of Cu NCs@ESM composite. In addition, the yellow color of the exhibitedasignificantchange,resultingineasyoxidationofCuNCsandfluorescencequenchingof fabricated composite, which was the characteristic color of formed ultralfine Cu NCs, was found to CuNCs@ESMcomposite. Inaddition,theyellowcolorofthefabricatedcomposite,whichwasthe fade obviously in the presence of ethanol (Figure S25a). Fascinatingly, the red fluorescence could be characteristiccolorofformedultralfineCuNCs,wasfoundtofadeobviouslyinthepresenceofethanol recovered when the quenched composite was replaced in a reducing agent solution such as sodium (FigureS25a). Fascinatingly,theredfluorescencecouldberecoveredwhenthequenchedcomposite wboarsorheypdlarciedde i(nNaaBreHd4u),c ianngda tgheen ytesolllouwti ocnolsourc rheaasppsoedairuedm, bwohroichhy sdhroidwee(dN tahBeH pr),oamnidset hoef ytheell orwecycoclleodr 4 ethanol sensing application (Figure S25b). reappeared,whichshowedthepromiseoftherecycledethanolsensingapplication(FigureS25b). FFiigguurree 55.. SSoollvveenntt eeffffeeccttss ooff CCuu NNCCss@@EESSMM ggeenneerraatteedd bbyy VVCC rreedduuccttiioonn.. ((aa)) tthhee ssoollvveennttss aarree ((11)) wwaatteerr;; ((22)) aacceettoonnee;; ((33)) ffoorrmmaallddeehhyyddee;; ((44)) mmeetthhaannooll;; ((55)) eetthhyylleennee ggllccyyccooll;; ((66)) iissoopprrooppaannooll;; ((77)) nn--bbuuttyyll aallccoohhooll;; ((88)) etehthyylal caectaettea;te(9; )(c9y)c lcoyhcelxoahneex;a(n1e0;) e(1th0a) neotlh,raensople, crtievsepleyc;t(ibv)eTlyh; e(rbe)s pTohnes eroefspproenpsaer eodf CpureNpCarse@dE SCMu tNoCetsh@aEnSoMls otolu ettihoannwoli tsholduitfifoerne wntitvho lduimffeerefrnatc vtioolnusm,fer ofrmac0titoon1s,% fruonmd e0r to36 15%n munUdeVr l3ig65h tn.m UV light. 3.4. Surface Patterning on ESM Substrate Due to the excellent stability and strong fluorescence of the prepared monolithic Cu NCs@ESM in dried form, it was possible to create fluorescent patterns on the surface of ESM employing the proposed facile and green route employing VC as the reducing reagent. For example, a red Materials2018,11,1913 10of16 3.4. SurfacePatterningonESMSubstrate DuetotheexcellentstabilityandstrongfluorescenceofthepreparedmonolithicCuNCs@ESM in dried form, it was possible to create fluorescent patterns on the surface of ESM employing Materials 2018, 11, x FOR PEER REVIEW 10 of 16 the proposed facile and green route employing VC as the reducing reagent. For example, a red flfluuoorreesscceenntt ssmmiilliinngg fafcaec eanadn d“C“uC-Nu--NC--sC”- sle”ttleertst ewrserwe oebretaoinbetdai bnye dsimbyplsyi mpapinlytinpga itnhteimng onth ae mpieocne oaf pEiSeMce soufbEstSrMates uwbisthtr aCtueSwOi4t hsoCluutSioOn4 asso l“uintiko”n faosll“oiwnked” fboyl loVwCe idncbuybaVtCionin ucnudbearti oanlkaulnindee rcoanlkdaitliionne c(Foingduirteio n6)(. FMiguorree 6i)m.pMorotraentilmy,p othrtisa nwtlyo,rkth icsowulodr kbeco uemldpbloeyeemd pfloory e“dhifdodre“nh”i dwderinti”nwg raitnindg aanntdi- aconutin-ctoeurfnetietirnfegi taipnpglaicpaptiloicnast.i ons. FFiigguurree 66.. PPhhoottooss ooff tthhee mmoonnoolliitthhiicc CCuu NNCCss@@EESSMM ffaabbrriiccaatteedd bbyy VVCC rreedduuccttiioonn iinn ddrriieedd ffoorrmm uunnddeerr vviissiibbllee lliigghhtt ((aa)) aanndd 336655 nmnm UUV Vliglhigth (ct)(; cS)u;rSfuacrfea fcleuoflrueoscreenscceen pcaettpearnttienrgn ionfg smofilsinmgi lfiancge (fbac) ean(bd) “aCnud- “Cu-N-C-s” letters (d) obtained by simply writing the patterning on a piece of ESM with CuSO N-C-s” letters (d) obtained by simply writing the patterning on a piece of ESM with CuSO4 solution4 solutionas“ink”followedbyNaOHandVCincubation. as “ink” followed by NaOH and VC incubation. 3.5. MonolithicCuNCs@ESMCompositeasHg2+ResponsiveStrips 3.5. Monolithic Cu NCs@ESM Composite as Hg2+ Responsive Strips Developing solid state fluorescent materials for sensing purposes (a good example is pH Developing solid state fluorescent materials for sensing purposes (a good example is pH testing testing paper) is of great significance with the advantages of reducing liquid handling operations paper) is of great significance with the advantages of reducing liquid handling operations (such as (such as accurate volume measurements) and greatly lowered detection costs, which is especially accurate volume measurements) and greatly lowered detection costs, which is especially useful in usefulincircumstancesofin-fieldorPOCquantitativeorsemi-quantitativetests. Mercuryisahighly circumstances of in-field or POC quantitative or semi-quantitative tests. Mercury is a highly toxic toxicheavymetalelementthatiswidelydistributedintheenvironment. Thereisastrongdemandto heavy metal element that is widely distributed in the environment. There is a strong demand to developlow-costandefficienttechniquesforHg2+detection. Asaproof-of-conceptdemonstration, develop low-cost and efficient techniques for Hg2+ detection. As a proof-of-concept demonstration, theas-preparedCuNCs@ESMwasusedasvisible“turn-off”stripsensorforHg2+withsatisfactory the as-prepared Cu NCs@ESM was used as visible “turn-off” strip sensor for Hg2+ with satisfactory sensitivityandselectivity. AsshowninFigure7b,thefluorescenceofCuNCs@ESMwasquenched sensitivity and selectivity. As shown in Figure 7b, the fluorescence of Cu NCs@ESM was quenched completelybydippingthestripinanHg2+solutionfor1h,whilethefluorescenceintensitywasalmost completely by dipping the strip in an Hg2+ solution for 1 h, while the fluorescence intensity was unchangedwhenincubatedwithothermetalions(Mn2+, Co2+, Cd2+, Ba2+, Zn2+, Pb2+, Al3+, Fe3+, almost unchanged when incubated with other metal ions (Mn2+, Co2+, Cd2+, Ba2+, Zn2+, Pb2+, Al3+, Fe3+, Cu2+, K+, Na+) at the concentration of 500 µM. The current results show that the concentration of Cu2+, K+, Na+) at the concentration of 500 μM. The current results show that the concentration of Hg2+ Hg2+ aslowto50µMcouldbevisiblyrecognizedbydistinguishablefluorescencequenchingfromthe as low to 50 μM could be visibly recognized by distinguishable fluorescence quenching from the backgroundeasily(Figure7a). Thepossiblequenchingmechanismisattributedtothehigh-affinity mbaectkagllroopuhnidli ceainsitleyr a(cFtiigounrse b7eat)w. Tehene pthoessdib10lec qeunteenrcshoinfgH mg2e+ch(5adn1is0m) a insd atdtr1i0bcuetnedte rtos othfeC hui+gh(-3adf1fi0n)iitny metallophilic interactions between the d10 centers of Hg2+ (5d10) and d10 centers of Cu+ (3d10) in the Cu the Cu NCs embedded in ESM. In addition, the formation of certain complexes by coordination NCs embedded in ESM. In addition, the formation of certain complexes by coordination and andelectrostaticattractionsbetweenHg2+ andtherichfunctionalgroups(e.g.,hydroxyl,carboxyl, electrostatic attractions between Hg2+ and the rich functional groups (e.g., hydroxyl, carboxyl, amino aminoandthiol)intheESMplatformwasnotunexpected. Overall,thesurfacecapping-ligandsand and thiol) in the ESM platform was not unexpected. Overall, the surface capping-ligands and charge states of these Cu NCs were greatly changed in the presence of Hg2+ ions mainly due to the aforementioned interactions, which leads to the effective fluorescence quenching [49].