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Journal of the Chilean Chemical Society

versión On-line ISSN 0717-9707

J. Chil. Chem. Soc. vol.57 no.2 Concepción  2012 

J. Chil. Chem. Soc., 57, N° 2 (2012), págs: 1147-1149.





Key Laboratory of Chemical Sensing & Analysis in Universities of Siman), China.
School of Chemistry and Chemical Engineering, University of Jinan, Jinan 250022,
China. of Shandong (University University of Jinan, Jinan 250022, China.


The copolymerization of carbazole(C) and poly3-ethyl-3-({[6-(3-thienyl)hexyl]oxy}-methyl)oxetane(PTO) was successfully achieved electrochemically in CH2Cl2 containing 25% boron trifluoride diethyl etherate BFEE(by volume) as supporting electrolyte by direct anodic oxidation of the monomer mixtures on platinum or an optically transparent ITO electrode. As-formed copolymer own the advantages of PTO, such as good electrochemical behaviors, excellent ambient stability. The structure of the copolymer were investigated by UV-vis, fluorescence spectra and thermal analysis, respectively. The fluorescence spectra indicate that PPTOC films are yellow-light emitters. Thermal analysis studies confirmed PPTOC has a good thermal stability.

Keywords Polythiophene; Electrochemical polymerization; carbazole; Copolymerization; Boron trifluoride diethyl etherate.



Inherently conducting polymers with π-conjugated electronic structures have been widely investigated since the late decades [1-3] due to their potential industrial applications based on their high conductivity and organic light-emitting. Conducting polymers are currently the subject of a board research area, especially for the applications in electronic and electrochemical devices such as organic field-effect transistors(OFETs),[4] organic light-emitting diodes(OLEDs),[5] polymer solar cells(PSCs),[6] and sensors. [7] Among these polymers, Poly(thiophenes) and poly(fluorene) have been received considerable attention. Such as poly(thiophenes) have been used in the development of electronic,[8] energy storage batteries,[9] photochromic devices,[10] and nonlinear optical devices.[11] The synthesis of conducting polymer films has been also an increasingly important subject of intensive research.[12-14]

Polythiophenes(PTs) and their derivatives, as a class of conducting polymers, have attracted considerable attention due to their good conductivity and chemical stability in both the neutral and doped states.[15] To improve the optoelectronic properties and to realize the special applications, chemical modifications have been well performed,[16] one of which is the introduction of substituent with functional groups. So we synthesized a novel oxetane-functionalized cross-linkable conjugated polymer(PTO).[17]

It is well known that copolymerization is one of efficient approaches to modify the properties of conducting polymers, which can produce copolymers with properties being intermediate between individual polymers. By means of the electrochemical copolymerization, some new conducting polymers have been prepared with several obvious advantages, such as variation of electrical conductivity, enhancement of electrochemical activity, and improvement of thermalstability.

In this paper we report on the use of oxetane-functionalized cross-linkable conjugated polythiophene(PTO) and carbazole (C) were copolymerized successfully by direct electrochemical oxidation in CH2Cl2 containing additional 25% (by volume) BFEE. The electrochemistry of copolymers(PPTOC) were studied. In addition, the spectroscopic properties, and thermal stability of the copolymer were also investigated in detail.


2.1. Materials

3-(6-Bromohexyl)thiophene (BHT) was synthesized by reaction of 3-bromothiophene (aladdin) with 1,6-dibromohexane (aladdin) in hexane solution using BuLi (aladdin) as reducing agent under the atmosphere of N2 as illustrated in Scheme 1. Boron trifluoride diethyl etherate (BFEE), Sinopharm Chemical Regagent Co., Ltd) was distilled and stored at -20□ before use.

Scheme 1: (a) BuLi, toluene, THF, reflux, 1,6-dibromohexane, THF; (b)3-ethyl-3-oxetanemethanol, NaOH, toluene, reflux, 8h; (c) BFEE, CH2Cl2; (d) BFEE, CH2Cl2.

Preparation of TO

The oxetane-substituted conjugated polymer was prepared by Scheme 1.[17] 1H NMR (CDCl3), δ (ppm): 7.25 (t, 1H), 6.92(t, 2H), 4.46 (d, 2H), 4.36(d,2H), 3.53 (s, 2H), 3.47(t, 2H), 2.64 (t, 2H), 1.78 (m, 2H), 1.61(m, 4H), 1.39(m, 4H), 0.90 (t, 3H). We use toluene instead of hexane, which yied 72%, better than 63%.

Chemical Ploymerizations

PTO via BFEE to chemical ring opening.[18] °C, C1(1.2x10-2mol, 2.976g), CH2Cl29.6ml, BF3O(C2H5)2 (3x10-3mol, 0.768ml). After 48h, ethanol end the reaction, then extracted with CH2Cl2 and washed with water (3x200 mL). The organic layer was dried over anhydrous MgSO4, filtered, and concentrated. Electrochemical Polymerizations.

PPTOC electrochemical by BFEE. High quality freestanding polythiophene network films were synthesized successfully in CH2Cl2 containing additional 25% (by volume) BFEE by direct anodic oxidation.

2.2. Characterization

All reactions were carried out under a dry nitrogen atmosphere. CH2Cl2 were distilled over calcium hydride. All solvents were distilled under nitrogen and saturated with nitrogen prior to use. UV-visible spectra were taken by using Perkin Elmer Lambda 900 UV-vis-NIR spectrophotometer. The 1H-NMR spectrum was recorded on a Bruker AV 400 NMR spectrometer and CDCl3 was used as the solvent. The thermogravimetric analysis(TGA) was performed with a thermal analyzer of Netzsch TG 209. The fluorescence properties were determined with Hitachi F-4500 fluorescence spectrophotometer.


3.1. Electrochemistry copolymerization

The successive cyclic voltammograms (CVs) of mixtures of the two monomers with various feed ratios on a Pt electrode in BFEE and CH2Cl2 were shown in Figure 1 and Scheme 2. C could be reduced and oxidized between -0.68 and 0.20 V (Fig. 1 a). On the other hand, CVs of PTO:C(1:3) showed broad redox waves with reduction and oxidation peaks at -0.72 and 0.30 V (Fig. 1 b), CVs of PTO:C(1:1) showed broad redox waves with reduction and oxidation peaks at -0.73 and 0.35 V (Fig. 1 c), CVs of PTO:C(3:1) showed broad redox waves with reduction and oxidation peaks at -0.68 and 0.29 V (Fig. 1 d).

Figure 1: Cyclic Voltammograms of C (a), PTO:C(1:3) (b), PTO:C(1:1) (c), PTO:C(3:1) (d), in CH2Cl2 containing 25% BFEE (by volume) BFEE. Potential scan rate: 100 mV.s-1.

It is clearly shown that on the first CV cycle, the current on the reverse scan was higher than that on the forward scan. The formation of this loop was characteristic of nucleation processes and only appeared on the first CV cycle. At the same time, with the potential scans continues, a polymer film was formed on the electrode surface. The increases of the redox wave currents implied that the amount of the polymer on the electrode surface has increasing. The potential shift of this maximum provided information about the increase of the electrical resistance in the polymer film and the over-potential was needed to overcome the resistance. All these phenomena indicated that high-quality PPTOC films were formed on the anode surface.

3.2 UV-vis and Fluorescence Spectra

The UV-visible spectra of C, PTO prepared from CH2Cl2, PPTOC [PTO:C(3:1)]prepared from CH2Cl2 containing 25% BFEE(by volume) BFEE are shown in Figure 2. The UV spectrum of the monomer C shows peaks at 235, 291 nm. PTO shows peaks at 236 nm. On the contrary, the spectra of the copolymer have a much broader absorption at 308, 373, 698 nm. The longer wavelength in the spectra indicated a longer polymer sequence.[19] These spectral results also confirmed a conjugated copolymer formation with a broad molarmass distribution.

Figure 2: UV-visible spectra of C, PTO in CH2Cl2, and the PPTOC [PTO:C(3:1)] films coated on an optically transparent ITO electrode.

The emission spectra of the C, PTO, PPTOC [PTO:C(3:1)] as shown in Figure 3. As shown in the figure, an obvious emission peak was found at 314 nm for PTO and 341, 354 nm for C, while the emission peak of the PPTOC films was found at 392, 418, 440 nm. The red shift of emission peak indicated that longer conjugation PPTOC was formed.[20] These results imply that PPTOC may be used in yellow light-emitting material.

Figure 3: Fluorescence spectra of C, PTO in CH2Cl2 and the PPTOC [PTO:C(3:1)] films coated on an optically transparent ITO electrode.

3.3 Thermal Analysis

The polymer films prepared electrochemically by using CH2Cl2 containing 25% BFEE(by volume) thermal analysis of PPTOC [PTO:C(3:1)] was shown in Figure 4. The thermal analysis of PPTOC was tested under a nitrogen stream from 300 to 1000 K with a heating rate of 10 K/min. The highest temperature 1030K is much higher than 680K[17]. These results imply that chemical ploymerizations and electrochemistry formed network PPTOC. There are two steps in weight loss. The first one is from 300 to 400 K, up to 10%, which can be ascribed to water evaporation or other moisture trapped in the polymer. The second occurred from 400K to 580K with a weight loss 15%.This was mainly due to the ions doped polymer degradation and the degradation of the polymer contained in the oligomers. The main one occurred from 580 K to 750K, up to 33%, which was attributed to the degradation radiation of the PPTOC. The main weight loss of PPTOC was found from 750 K to 1000 K with a weight loss of 34%, which results from the degradation of the PPTOC main backbone. All these results indicate that PPTOC has a good thermal stability.

Figure 4: TGA curves of PPTOC [PTO:C(3:1)] films obtained potentiostatically at 1V vs Pt from CH2Cl2 containing 25% BFEE(by volume) .


The electrochemical copolymerization of PTO and C successfully realized in CH2Cl2 containing 25% BFEE(by volume) by direct anodic oxidation of PTO and C monomer mixtures. The copolymers showed many advantages, such as good electrochemical behavior, good mechanical properties, and favorable thermal stability. Fluorescence studies revealed that the copolymer was good yellow light emitter. Under these conditions, copolymer films combined with the advantages of both PTO and C may meet the application in LEDs as light-emitting films.



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(Received: September 23, 2011 - Accepted: January 13, 2012).

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