导电聚合物的电化学制备和电化学性质研究——中国科学院有机固体重点实验室导电聚合物电化学研究工作简介(I)

简要介绍本研究组自上世纪80年代以来在导电聚合物的电化学制备和电化学性质研究中取得的一些主要成果,包括吡咯电化学聚合条件的影响、电化学聚合反应机理及其反应动力学、导电聚吡咯的两种掺杂结构及其两步电化学氧化还原过程和电化学过氧化的机理、导电聚苯胺的电化学性质、导电聚合物稳定性的电化学解释等等.     

Conducting poly(3,4-ethylenedioxythiophene)-montmorillonite exfoliated nanocomposites

Exfoliated nanocomposites formed by poly(3,4-ethylenedioxythiophene) and different concentrations of non-modified montmorillonite (bentonite), which range from 1% to 10% w/w, have been prepared by anodic electropolymerization in aqueous solution. Analyses of the electrochemical and electrical properties reveal that the electroactivity of the nanocomposites is higher than that of the individual homopolymer, while the electrical conductivity of the two systems is practically identical. On the other hand, the exfoliated distribution of the clay in the polymeric matrix and the morphology of the prepared materials have been characterized using transmission electron microscopy, X-ray diffraction and atomic force microscopy. The overall of the results represents a significant improvement with respect to other nanocomposites constituted by conducting polymers and clays, including those involving poly(3,4-ethylenedioxythiophene), and evidences the reliability of the preparation procedure employed in this work.     

Cation template assisted electrosynthesis of a highly π-conjugated polythiophene containing oligooxyethylene segments

A polythiophene precursor involving two bithiophene groups linked by an oligooxyethylene chain has been synthesized. Electropolymerizations performed in the presence of tetrabutylammonium, lithium, sodium and barium perchlorate show that the nature of the electrolyte cation strongly affects the polymerization process. The electrochemical and spectroelectrochemical properties of the resulting polymers show that the presence of barium cation in the electrosynthesis medium leads to a 300 mV decrease in the oxidation potential of the polymer, together with a significant red shift in the absorption maximum providing conclusive evidence for a metal template effect during electropolymerization.     

Properties of nanometric and micrometric multilayered films made of three conducting polymers

The electrochemical, electrical and morphological properties of multilayered films formed by alternated layers of poly(3,4-ethylenedioxythiophene), polypyrrole, and poly[N-(2-cyanoethyl)pyrrole], which were prepared by electrochemical layer-by-layer deposition, have been investigated and compared with those of multilayered films formed by two conducting polymers. Results indicate that the electrochemical behavior of the films formed by three conducting polymers depends on the micrometric or nanometric thickness of the layers. Thus, the electroactivity increases until the thickness of these films reaches a threshold value (∼2 μm), while the electrostability of the films is very remarkable when their thickness is close to ∼4 μm or higher. On the other hand, comparison between multilayered systems made of two and three conducting polymers indicates that the third component introduces heterogeneity in the interfaces between consecutive layers, reducing the ability to store charge. Among the latter, multilayered films formed by poly(3,4-ethylenedioxythiophene) and polypyrrole have been found to be particularly electroactive and electrostable. The surface morphology and topography of the layers have been used to rationalize the electrochemical properties of the different materials.     

New conducting polythiophenes containing substituted polyfluorinated alkoxy chain

A series of poly(fluoroalkoxy thiophenes) have been prepared by electrochemical and chemical polymerization respectively. The substitution of thiophene by polyfluorinated alkoxy chains affords more favorable structures in electronic effect and higher stabilities of their polymers than conventional alkoxy chain substituted polymers.     

Synthesis and electrochemical investigation of <Emphasis Type="Italic">beta</Emphasis>-substituted thiophene-based donor–acceptor copolymers with 3,4-ethylenedioxythiophene (EDOT)

The present work reports the synthesis of four electron-acceptor beta-substituted thiophenes that were studied as monomers for electrochemical polymerization with 3,4-ethylenedioxythiophene (EDOT), an electron-donating monomer, aiming the combination of electron-acceptor and donor monomer thiophene to a simpler and convenient build up of novel donor–acceptor copolymeric materials via electrochemical polymerization. Four novel copolymers poly(EDOT-co-3-thiophene phenylacetate), (PEDOT-co-PPhTAc-2a), poly(EDOT-co-3-thiophene(4-nitrophenyl)acetate) (PEDOT-co-PPhTAc-2b), poly(EDOT-co-3-thiophenephenylcarboxylate) (PEDOT-co-PPhTCb), and poly(EDOT-co-3-(phenoxymethyl)thiophene) (PEDOT-co-PPhOMT) were electrochemically polymerized. The monomers were characterized by spectrometric techniques (FTIR, ¹H NMR, and ¹³C NMR), and the copolymers were identified by electrochemical analyses and FT-IR. Although the corresponding homopolymers could not be obtained, in the presence of EDOT, the copolymers were formed in a quasi-reversible electrochemical kinetics. The infrared spectra of the copolymers as well the electrochemical profile corroborates their obtaining. The mass variation during the electrosynthesis was analyzed using a quartz crystal microbalance. The film’s morphologies were investigated by SEM. Interestingly, the combination of electron-rich monomer thiophene (EDOT) and these electron-deficient carboxy-substituted thiophenes might be a convenient building block couple to increase the performance control of physic-chemical properties of mixed polythiophenes with innovative applications and they also showed a possible applicability as charge storage device.     

Electrochemistry of conjugated organic polymers

The electrochemistry of conjugated organic polymers such as polyaniline, polythiophene, and polypyrrole has been reviewed. The physical chemistry and, especially, the electrochemistry of conducting polymers (CP) are largely determined by their electrosynthesis conditions. The effects of such factors as the dopant, solvent, and base electrolyte on the preparation and electrochemical n- and p-doping of CP have been considered. The outstanding features of the electrochemistry of CP have been delineated. The prospects for the use of CP as active cathode and anode materials in chemical cells have been discussed.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 30, No. 3, pp. 111–129, May–June, 1994.     

Ultrathin conjugated polymer network films of carbazole functionalized poly(p-phenylenes) via electropolymerization

Ultrathin films of a cross-linked and chemically distinct conjugated poly(p-phenylene) network via electropolymerization are described. The amphiphilic network precursor was synthesized by incorporating the alkoxy carbazole group (-O(CH2)5Cb) to a poly(p-phenylene) (C6PPPOH) backbone. In order to investigate the combined thin film electrochemical and photophysical properties of poly(p-phenylene)s and polycarbazole conjugated polymers, C6PPPC5Cb was deposited on substrates using the Langmuir Blodgett Kuhn (LBK) method. The monolayer isotherm of the polymer, C6PPPC5Cb, showed a liquid expanded region slightly different from the parent polymer C6PPPOH. Multilayers (up to 30 layers) were transferred to different substrates such as quartz, gold coated LaSFN9 and ITO substrates for analysis. For conversion to a conjugated polymer network (CPN) film, the electroactive carbazole group was electropolymerized using cyclic voltammetry (CV) resulting in polycarbazole linking units. The differences in the film properties and corresponding changes in the electrochemical behavior indicate the importance of film thickness and electron/ion transport process in cross linked network films. From the electrochemical studies, the scan rate was found to have a considerable effect on electropolymerization with higher oxidation and reduction peak values found for the rigid network polymer compared to the uncrosslinked polymers.     

Novel electrochemical synthesis and characterisation of poly(methyl vinylsilane) and its co-polymers

The electrochemical synthesis and characterisation of poly(methyl vinylsilane) and a series of poly(methyl vinylsilane-co-metallocenes) network polymers are described in detail. This class of polymers are not accessible through Wurtz coupling reaction and are however prepared by electro-reduction of dichloro methyl vinylsilane in a non-aqueous system using aluminum electrodes in a single compartment cell. These polymers have been characterised using UV, FTIR, XRD, SEM and NMR spectral techniques. Cyclic voltammetric studies of the above polymers reveal their conducting behavior. These polymers show optical properties as explained from the results. Polymers of this type are proposed as potential soluble precursors for SiC and metal doped SiC materials.     

Saccharide imprinting of poly(aniline boronic acid) in the presence of fluoride

A new approach for the electrosynthesis of saccharide-imprinted poly(aniline boronic acid) is described. The method involves the formation of a saccharide-aminophenylboronic acid complex in the presence of fluoride to allow the electropolymerization of a self-doped, molecularly imprinted polyaniline. The formation of the anionic monomer complex enables electrochemical polymerization at near neutral pH (5-7) ensuring the incorporation of saccharide in the resulting, self-doped polymer. In this work, films were imprinted with D-fructose where saccharide-aminophenylboronic acid complexation occurred in the presence of one equivalent of fluoride. The selectivity toward D-fructose relative to D-glucose showed an increase of over 25% as a result of imprinting. In addition to the enhanced selectivity, to the best of our knowledge this is the first example of the electropolymerization of a self-doped polyaniline homopolymer under neutral pH conditions.     

Conducting polyfurans by electropolymerization of oligofurans

Polyfurans have never been established as useful conjugated polymers, as previously they were considered to be inherently unstable and poorly conductive. Here, we show the preparation of stable and conducting polyfuran films by electropolymerization of a series of oligofurans of different chain lengths substituted with alkyl groups. The polyfuran films show good conductivity in the order of 1 S cm^–1, good environmental and electrochemical stabilities, very smooth morphologies (roughness 1–5 nm), long effective conjugation lengths, well-defined spectroelectrochemistry and electro-optical switching (in the Vis-NIR region), and have optical band-gaps in the range of 2.2–2.3 eV. A low oxidation potential needed for polymerization of oligofurans (compared to furan) is a key factor in achievement of improved properties of polyfurans reported in this work. DFT calculations and experiments show that polyfurans are much more rigid than polythiophenes, and alkyl substitution does not disturb backbone planarity and conjugation. The obtained properties of polyfuran films are similar or superior to the properties of electrochemically prepared poly(oligothiophene)s under similar conditions.     

Electrochemical behaviour of conducting polymers obtained into clay-catalyst layers. An in situ Raman spectroscopy study

In this paper we present the study of the electrochemical properties of the following conducting polymers: poly(o-anisidine), polyaniline and copolymers of aniline and o-anisidine obtained by a new synthetic method. The polymers are synthesized in free-of-acid conditions, using an activated montmorillonitic clay catalyst, known as Maghnite-H⁺ (Mag-H) as proton source. The electrochemical behaviour of poly(o-anisidine) created using Mag-H (PoANI-MagH) and their copolymers with aniline is quite different of those polymers created in HCl solution. In situ Raman data suggest that the structure of PoANI-MagH is a mixture of conducting (polyaniline-type) and redox (phenoxazine or phenazine-type) segments.     

Poly(neutral red): Electrosynthesis,Characterization, and Application as a Redox Mediator

The synthesis by electropolymerization, the characterization, and applications of poly(neutral red) (PNR), including as a redox mediator, are reviewed. PNR's high electrical conductivity and its redox characteristics have led to special applications of the polymer, and it has been used for the development of electrochemical and optical sensors. Moreover, the attractive properties of PNR allow it to be applied in the development of electrochemical biosensors. Future perspectives are indicated.     

Self-doping effect in poly(o-methoxyaniline)/poly(3-thiopheneacetic acid) layer-by-layer films

Nanostructured films from two conducting polymers, poly(o-methoxyaniline) (POMA) and poly(3-thiopheneacetic acid) (PTAA), were fabricated with the layer-by-layer (LBL) technique. The electrochemical response of the LBL films differs from that of a POMA cast film, even in a potential range where PTAA is inactive. This is attributed to differences in the diffusion-controlled charge and mass transport, where distinct ionic species participate in the LBL films, as demonstrated by quartz crystal microbalance measurements. The results show that the transport properties of conducting polymers can be changed by alternation with layers of appropriate materials in LBL films.     

Electrochemical polymerization of poly(thiophene-3-acetic acid), poly(thiophene-co-thiophene-3-acetic acid) and determination of their molar mass

The electrochemical preparation and molar mass characterization of conducting polymers, poly(thiophene-3-acetic acid) (poly(TPAA)), and poly(thiophene-co-thiophene-3-acetic acid) (poly(TP/TPAA)) are reported. RRDE results revealed that, unlike other conducting polymers, current efficiency during the deposition of poly(TPAA) is by far less than 1 due to significant solubility of the polymer. Up to 48% of the oxidation products of the disc electrode can dissipate into the bulk solution. These dissipated species are polymers in oxidized form and reactive towards reductant originally present in the coating solution. The low current efficiency necessitates the use of relatively high monomer concentration and high polymerization potential to obtain a conducting poly(TPAA) film. Characterization with gel permeation chromatography (GPC) of molar mass and its distribution has been carried out. The results show that up to 65% to 85% of the whole polymers are comprised of big molecules containing over 2000 monomer units, which indicates the possibility of cross-linking of polymer chains. The remaining parts of the polymers are relatively short chains containing several to dozens of monomers. Increase of TPAA content in the copolymers leads to better solubility and higher molar mass. The latter is accompanied by greater electronic conjugation in the polymer chains.     

Considerations about the electrochemical estimation of the ionization potential of conducting polymers

The energy gap and ionization potential of some conducting polymers such as polypyrrole and the polythiophene derivatives, poly(3-methylthiophene) and poly(3-hexylthiophene), are estimated using optical and electrochemical techniques. With these parameters we have constructed the energy level diagrams of the polymers. Electronic Publication     

Conducting polythiophenes with a broad spectrum of reactive groups

The development of reliable and reproducible chemistries for the immobilization of biomolecules to a conducting polymer is a key challenge in the design and preparation of a CP‐based biosensor. In this article, the syntheses and electropolymerization of a series of new 3‐alkylthiophene derivatives functionalized with the most used reactive groups in immobilization chemistry, including maleimide, azide, and anhydride, are described. Despite the nucleophilic or electrophilic nature of the reactive groups, the synthesized thiophene monomers exhibit rather good polymerizability, and the reactive groups withstand the polymerization conditions and are correctly incorporated into the resulting electroactive polymers. The reactivity of the pendant reactive groups of the resulting polymers to attach biomolecules has been examined with different redox‐active, photoactive compounds as well as recognition elements as model compounds. It has been confirmed that with well‐established procedures developed for the immobilization of enzymes, the model compounds can be easily and selectively bound onto these new conducting polymers without the loss of their optical and electrochemical activity. Therefore, these conductive materials with a broad spectrum of reactive groups will provide a useful platform for developing CP‐based biosensors for a wide range of applications. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 4547–4558, 2005     

碳纳米管/聚对甲基吡啶修饰电极测定硝基苯甲酸

采用滴涂法和循环伏安法在玻碳电极上电沉积一层稳定的单壁碳纳米管/聚对甲基吡啶纳米薄膜(SWNTs/POMP)。研究了邻、对硝基苯甲酸在此修饰电极上的电化学行为,建立了电化学同时测定邻、对硝基苯甲酸的新方法。实验结果表明:在0.1 mol/L HClO4溶液中,邻、对硝基苯甲酸在SWNTs/POMP电极上发生不可逆的还原反应,由于碳纳米管和聚合物薄膜的协同效应,SWNTs/POMP电极对邻、对硝基苯甲酸有很好的的电催化作用,并对其响应进行了定量分析。     

Theoretical study of chloropyrroles as monomers for new conductive polymers

Electronic, structural, electrochemical, and spectroscopic properties of all ground-state neutral and singly ionized chlorine-substituted pyrroles and hexa(3-chloropyrrole) oligomer are studied using the density functional theory B3LYP method with the 6-31G(d,p) basis set. The effects of the number and position of the substituents on the electrochemical properties of the pyrrole ring have been studied and analyzed both quantitatively and qualitatively. By using the optimized structures obtained for these molecules and their cations, IR and NMR spectra have been predicted. The results of this study, including spin and charge distributions, show that, among all of these compounds, 3-chloropyrrole has the most suitable conditions for electropolymerization.     

Electrochemically synthesized polymers in molecular imprinting for chemical sensing

This critical review describes a class of polymers prepared by electrochemical polymerization that employs the concept of molecular imprinting for chemical sensing. The principal focus is on both conducting and nonconducting polymers prepared by electropolymerization of electroactive functional monomers, such as pristine and derivatized pyrrole, aminophenylboronic acid, thiophene, porphyrin, aniline, phenylenediamine, phenol, and thiophenol. A critical evaluation of the literature on electrosynthesized molecularly imprinted polymers (MIPs) applied as recognition elements of chemical sensors is presented. The aim of this review is to highlight recent achievements in analytical applications of these MIPs, including present strategies of determination of different analytes as well as identification and solutions for problems encountered.