直接甲醇燃料电池阳极催化剂及甲醇氧化稀土助催化剂剂研究

燃料电池以其高效、环境友好的发电方式，被誉为21世纪的能源技术。其中，直接甲醇燃料电池（DMFC）更以燃料甲醇来源丰富，价格低廉，储存、携带方便而成为近年的研究热点。但是，DMFC在其实用化之前还需要解决一些重要问题，其中的关键之一就是高性能的贵金属催化剂的研究。我们知道，甲醇的电化学活性要低于氢气三个数量级；而且甲醇在R表面进行电化学氧化时，其中间解离吸附产物会造成贵金属催化剂中毒，显著降低了催化剂的活性。因此，要使DMFC具有相当高的电流密度和运行稳定性，就需要对贵金属催化剂制备进行不断的研究和改进。在本文的工作中，主要从Pt/C催化剂的制备方法、新型碳纳米管载体、稀土助催化剂等三个方面进行了研究和探索，取得的具体结果如下：1．Pt／C催化剂制备方法的研究与改进（1）在本组已有的研究结果基础上，对预沉积还原法进行了一些改进，采用原子吸收光谱（AAS）进行表征，发现Pt的利用率得到了明显的提高。采用X射线衍射。（RD）、透射电子显微镜（TEM）和BET表征铂的粒径、晶态结构和催化剂特性，分析表明，经过改进的预沉积还原法制备的催化剂仍然具有良好的分散性、较小的粒径、较低的晶态结构和良好的催化剂特性，电化学测试证明其性能要优于同等的E-TEK催化剂。（2）借鉴冶金学中的相关技术，提出了一种新的Pt/C催化剂制备方法一程序升温焙烧法。该方法的具体步骤增强了金属催化剂粒子和碳载体之间的相互作用力，提高了碳载体的导电性，并且形成了部分有利于催化反应进行的活性晶态结构。得到的R／C催化剂获得了近似E-TEK催化剂的催化活性，在具体方法上仍有改进的潜力。采用了同（1）的催化剂表征方法。2．甲醇电化学氧化稀土助催化剂研究在直接甲醇燃料电池Pt/C催化剂的研究过程中，一个重要的方面就是助催化剂的研究，并且已经得到了较好的结果。本工作选用了稀土元素为研究对象，因为稀土元素属于过渡金属，具有丰富的d电子轨道，易于和金属形成强的类化学键的吸附作用，并且能够和有机小分子形成多种配位化合物。经过初步的工作，发现了有些稀土离子如Sm3+能够在Pt表面吸附并且对甲醇电化学氧化具有较稳定的促进作用，采用循环伏安法，计时电流，交流阻抗等电化学方法进行了表征。根据实验结果，对其反应机理进行了初步的探讨。3．碳纳米管（CNTs）作为贵金属催化剂载体的研究碳纳米管（CNTs）由于其结构上的特殊性（径向尺寸为纳米量级，轴向尺寸为微米量级）而表现出典型的一维量子材料，同时具有较高的机械强度和超常的电学性能，能够为化学反应提供纳米级的反应场所，因此受到了化学界包括电化学研究人员的极大关注。已经在作为贵金属催化剂载体方面进行了一些研究，本工作的主要内容就是针对Pt/CNTs催化剂对碳纳米管的要求，对其预处理方法进行了改进，采用了如（1）中的催化剂表征方法和（2）中的相关电化学方法进行测定，发现碳纳米管作为贵金属催化剂载体时，对它的纯化处理方法的不同明显地影响了其载体性质和催化剂的活性。

直接甲醇燃料电池甲醇替代燃料的研究

论文主要研究了直接甲醇燃料电池（DMFC）中三种甲醇替代燃料，二甲氧基甲烷（DMM）、乙醇和乙二醇及导致阳极催化剂中毒的吸附CO（COad）在光滑R电极及几种新的R基催化剂电极上的电氧化行为。结合对催化剂的X射线光电子能谱（xPS）、X衍射(XRD)、扫描电子显微镜（SEM）和热重分析（TG）表征，初步探讨了几种新催化剂对三种甲醇替代燃料的电催化活性要高于碳载R（PtC）催化剂的原因。另外，还研究了用表面活化处理来提高阳极催化剂对甲醇氧化的电催化活性的方法。本论文得到的主要结果如下：1．在研究DMM在不同条件下，在不同R基催化剂电极上的电化学氧化行为的基础上，发现碳载R和TiO2（Pt-TiO2／C）复合催化剂对DMM氧化的电催化活性要优于Pt/C电极。而Pt-TiO2／C催化剂在吸附Ho3+(Pt-TiO2-Ho3+/C)或Eu3＋（Pt-TiO2-Eu3＋/C）后，对DMM氧化的电催化活性比Pt-TiO2／C电极高。表明TiO2、Eu3+和Ho3+对DMM的氧化都有很好的促进作用，这主要是它们都能为DMM的氧化在电极表面提供更多的含氧物种。由于DMM本身在这些催化剂电极上的氧化性能不好，而且DMM容易在酸性溶液中水解，生成甲醇和甲醛，因此，DMM不是一种好的甲醇替代燃料。2．无论在中性介质中还是在酸性介质中，Eu3＋和Ho3＋对乙醇在R／C电极上的电化学氧化反应都有较好的促进作用，而Eu3＋的促进作用要大于H3+，Eu3＋和H3+在酸性溶液中的促进作用要大于在中性溶液中。无论是中性溶液还是酸性溶液中，吸附CO（COad）在Pt／C催化剂电极上在较正的电位处有一个很大的氧化峰，而在R-Eu3＋／C或R-H3＋／C催化剂电极上在较负电位处有两个小的氧化峰，表明吸附的Eu3＋和Ho3+对cood在R／C催化剂电极上的氧化都有很好的促进作用，主要表现在使Cood的吸附强度降低和吸附量减少。XPs测量表明，当R／C电极表面吸附了Eu3＋或H了十后，使催化剂中Pt和c土的电子云密度变小，因此使Pt对coad的吸附强度减弱。由于Eu3＋或H03＋在电极上吸附不是物理吸附，而是化学吸附，因此，它们与Pt的结合具有相对的稳定性。乙醇电氧化的中间产物，如COad等能强烈地吸附在R上，因此会使R中毒。而Eu3＋或H矿"能降低Coad在R上地吸附强度，因此，Eu3＋或H3+能促进乙醇在Pt／C电极上的电化学氧化反应。Pt-TiO2／C催化剂对乙醇氧化的电催化活性要高于R／C催化剂，表明TiO2对乙醇在R／C电极上的电化学氧化反应也有较好的促进作用。XPS的测量表明，TiO2的加入并不改变Pt的电子状态，因此，TiO2能促进乙醇电氧化反应的主要原因是TIOZ能为乙醇氧化提供含氧物种。实验结果表明，Eu3＋或H3+对乙醇在R-TiO2／C电极上的电化学氧化反应也有一定的促进作用。这是由于Eu3＋或H3+改变了R的电子状态，降低了乙醇电氧化中间产物，COod在Pt上的吸附强度，而TIOZ提供了COod的氧化所必须的含氧物种。3．无论是酸性溶液中还是中性溶液中，乙二醇在R-TiO2／C电极上的氧化活性比在R／C电极上高。这表明TIOZ能促进乙二醇在Pt上的电氧化反应。进一步的实验表明，TIOZ对COad在Pt催化剂电极上氧化的促进作用并不明显。XPS测量表明，这是由于TIOZ并不改变R的电子状态。所以，TiO2对乙二醇在Pt上的电氧化的促进作用只是基于提供乙二醇电氧化所需的含氧物种。无论是酸性溶液中还是中性溶液中，乙二醇在R-WO3／C电极上的氧化活性都比在R／C电极上高。这表明W03能促进乙二醇在R上的电氧化反应。进一步的实验表明，R-WO3／C电极对Coad氧化的电催化活性也要高于R／C电极，XPS测量表明，WO3会降低Pt的电子云密度。所以，WO3对乙二醇在R上的电氧化的促进作用除了提供含氧物种外，还由于它能降低R的电子云密度而降低了乙二醇电氧化中间产物。4．用四氢吠喃和丙酮混合溶液浸泡法对电极进行表面处理后能使Pt／C和Pt-WO3／C电极对乙醇和乙二醇氧化的电催化活性有很大的提高。其原因可能是Pt／C和Pt一w03／C电极在经表面处理后，在电极制备过程中带来的表面活性剂等杂质由于溶解在混合溶液中而被除去，Nafion也可能在用混合溶液浸泡后会发生一定程度的结构变化，因此，使活性中心的位点增加，从而增加了催化剂的电催化活性。另外，经表面处理后，Pt／C和Pt-WO3／C电极的活性中心的结构有一定的变化，使COad的吸附强度降低而容易氧化，降低了COad对催化剂的毒化作用，因而提高了电极对乙醇和乙二醇氧化的电催化活性。

Electrospun palladium nanoparticle-loaded carbon nanofibers and their electrocatalytic activities towards hydrogen peroxide and NADH

Palladium nanoparticle-loaded carbon nanofibers (Pd/CNFs) were synthesized by the combination of electrospinning and thermal treatment processes. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) images show that spherical Pd nanoparticles (NPs) are well-dispersed on the surfaces of CNFs or embedded in CNFs. X-ray diffraction (XRD) pattern indicates that cubic phase of Pd was formed during the reduction and carbonization processes, and the presence of Pd NPs promoted the graphitization of CNFs. This nanocomposite material exhibited high electric conductivity and accelerated the electron transfer, as verified by electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV).

In situ PEI and formic acid directed formation of Pt NPs/MWNTs hybrid material with excellent electrocatalytic activity

A hybrid material based on Pt nanoparticles (Pt NPs) and multi-walled carbon nanotubes (MWNTs) was fabricated with the assistance of PEI and formic acid. The cationic polyelectrolyte PEI not only favored the homogenous dispersion of carbon nanotubes (CNTs) in water, but also provided sites for the adsorption of anionic ions PtCl42- on the MWNTs' sidewalls. Deposition of Pt NPs on the MWNTs' sidewalls was realized by in situ chemical reduction of anionic ions PtCl42- with formic acid. The hybrid material was characterized with TEM, XRD and XPS. Its excellent electrocatalytic activity towards both oxygen reduction in acid media and dopamine redox was also discussed.

Polyaniline/Pt Hybrid Nanofibers: High-Efficiency Nanoelectrocatalysts for Electrochemical Devices

A simple and facile procedure to synthesize a novel hybrid nanoelectrocatalyst based on polyaniline (PANI) nanofiber-supported supra-high density Pt nanoparticles (NPs) or Pt/Pd hybrid NPs without prior PANI nanofiber functionalization at room temperature is demonstrated. This represents a new type of ID hybrid nanoelectrocatalyst with several important benefits. First, the procedure is very simple and can be performed at room temperature using commercially available reagents without the need for templates and surfactants. Second, ultra-high density small "bare" Pt NPs or Pt/Pd hybrid NPs are grown directly onto the surface of the PANI nanofiber, without using any additional linker. Most importantly, the present PANI nanofiber-supported supra-high density Pt NPs or Pt/Pd hybrid NPs can be used as a signal enhancement element for constructing electrochemical devices with high performance.

The preparation of high activity DMFC Pt/C electrocatalysts using a pre-precipitation method

It is suggested that a Pt/C cathodic catalyst for the direct methanol fuel cell (DMFC) can be prepared with a pre-precipitation method, in which, H2PtCl6 is precipitated onto the carbon black as (NH4)(2)PtCl6 before H2PtCl6 is reduced to Pt. The electrocatalytic activity of this Pt/C-A catalyst for oxygen reduction is excellent because the Pt/C catalyst prepared with this pre-precipitation method possesses a small average particle size, low relative crystalinity and a large electrochemically active surface area. In addition, the pre-precipitation method is simple and economical and it can be used to prepare a Pt/C catalyst on a large scale.

Structure-activity relationship of surfactant for preparing DMFC anodic catalyst

Three kinds of surfactants as stabilizer were applied to the preparation of electrocatalysts for direct methanol fuel cell (DMFC). The catalysts have been characterized by examining their catalytic activities, morphologies and particle sizes by means of cyclic voltammetry, chronoamperometry, X-ray diffraction and transmission electron microscopy (TEM). It is found that the surfactants with different structures have a significantly influence on the catalyst shape and activity. The catalysts prepared with non-ionic surfactants as the stabilizer show higher activity for direct oxidation of methanol. The structure-activity relationship (SAR) analysis has been explored and the effect of hydrophile-lipophile balance (HLB value) has also been discussed.

Ethanol crossover phenomena and its influence on the performance of DEFC

In the present work, Nafion (R) membrane porosity changes were determined in aqueous ethanol solutions with different concentrations by weighing vacuum-dried and ethanol aqueous solution equilibrated membranes at room temperature. The ethanol crossover rate through Nafion (R)-115 membrane at different temperatures and different concentrations had been investigated in a fuel cell test apparatus by using membrane gets higher as ethanol solution gas chromatography analysis. The experimental results show that the swelling degree of Nafion (R) concentration increases. The ethanol crossover rate increases with ethanol concentration and temperature increment. The single direct ethanol fuel cell (DEFC) tests were carried out to investigate the effect of ethanol concentration on ethanol crossover and consequently, on the open circuit voltage and the cell performance of DEFC. It can be found that ethanol crossover presented a negative effect on the OCV and the cell performance of DEFC. It can also be found that an improved DEFC performance was obtained as temperature increased although the ethanol crossover rate increased with temperature increment. (c) 2005 Elsevier B.V. All rights reserved.

Structure and chemical composition of supported Pt-Sn electrocatalysts for ethanol oxidation

Carbon supported PtSn alloy and PtSnOx particles with nominal Pt:Sn ratios of 3:1 were prepared by a modified polyol method. High resolution transmission electron microscopy (HRTEM) and X-ray microchemical analysis were used to characterize the composition, size, distribution, and morphology of PtSn particles. The particles are predominantly single nanocrystals with diameters in the order of 2.0-3.0 nm. According to the XRD results, the lattice constant of Pt in the PtSn alloy is dilated due to Sn atoms penetrating into the Pt crystalline lattice. While for PtSnOx nanoparticles, the lattice constant of Pt only changed a little. HRTEM micrograph of PtSnOx clearly shows that the change of the spacing of Pt (111) plane is neglectable, meanwhile, SnO2 nanoparticles, characterized with the nominal 0.264 nm spacing of SnO2 (10 1) plane, were found in the vicinity of Pt particles. In contrast, the HRTEM micrograph of PtSn alloy shows that the spacing of Pt (111) plane extends to 0.234 nm from the original 0.226 nm. High resolution energy dispersive X-ray spectroscopy (HR-EDS) analyses show that all investigated particles in the two PtSn catalysts represent uniform Pt/Sn compositions very close to the nominal one. Cyclic voltammograms (CV) in sulfuric acid show that the hydrogen ad/desorption was inhibited on the surface of PtSn alloy compared to that on the surface of the PtSnOx catalyst. PtSnOx catalyst showed higher catalytic activity for ethanol electro-oxidation than PtSn alloy from the results of chronoamperometry (CA) analysis and the performance of direct ethanol fuel cells (DEFCs). It is deduced that the unchanged lattice parameter of Pt in the PtSnOx catalyst is favorable to ethanol adsorption and meanwhile, tin oxide in the vicinity of Pt nanoparticles could offer oxygen species conveniently to remove the CO-like species of ethanolic residues to free Pt active sites. (C) 2005 Elsevier Ltd. All rights reserved.

Determination of ionic resistance and optimal composition in the anodic catalyst layers of DMFC using AC impedance

In the present study, a method based on transmission-line mode for a porous electrode was used to measure the ionic resistance of the anode catalyst layer under in situ fuel cell operation condition. The influence of Nafion content and catalyst loading in the anode catalyst layer on the methanol electro-oxidation and direct methanol fuel cell (DMFC) performance based on unsupported Pt-Ru black was investigated by using the AC impedance method. The optimal Nafion content was found to be 15 wt% at 75 degrees C. The optimal Pt-Ru loading is related to the operating temperature, for example, about 2.0 mg/cm(2) for 75-90 degrees C, 3.0 mg/cm2 for 50 degrees C. Over these values, the cell performance decreased due to the increases in ohmic and mass transfer resistances. It was found that the peak power density obtained was 217 mW/cm(2) with optimal catalyst and Nafion loading at 75 degrees C using oxygen. (c) 2005 International Association for Hydrogen Energy. Published by Elsevier Ltd. All rights reserved.

Highly conductive, methanol resistant fuel cell membranes fabricated by layer-by-layer self-assembly of inorganic heteropolyacid

Layer-by-layer (LBL) self-assembly is a simple and elegant method of constructing organic-inorganic composite thin films from environmentally benign aqueous solutions. In this paper, we utilize this method to develop proton-exchange membranes for fuel cells. The multilayer film is constructed onto the surface of sulfonated poly(arylene ether ketone) (SPAEK-COOH) membrane by LBL self-assembly of polycation chitosan (CTS) and negatively charged inorganic particle phosphotungstic acid (VIA). The highly conductive inorganic nanoparticles ensure SPAEK-COOH-(CTS/PTA)(n) membranes to maintain high proton conductivity values up to 0.086 S cm(-1) at 25 degrees C and 0.24S cm(-1) at 80 degrees C, which are superior than previous LBL assembled electrolyte systems.

Platinum-coated gold nanoporous film surface: Electrodeposition and enhanced electrocatalytic activity for methanol oxidation

This report describes the preparation of Pt-nanoparticle-coated gold-nanoporous film (PGNF) on a gold substrate via a simple "green" approach. The gold electrode that has been anodized under a high potential of 5 V is reduced by freshly prepared ascorbic acid (AA) solution to obtain gold nanoporous film electrode. Then the Pt nanoparticle is grown on the electrode by cyclic voltammetry (CV).

The mechanism of formic acid electro oxidation on iron tetrasulfophthalocyanine-modified platinum electrode

The mechanism of formic acid electrooxidation on iron tetrasulfophthalocyanine (FeTSPc) modified Pt electrode was investigated with electrochemical methods. It was found that a "third-body" effect of FeTSPc on Pt electrode predominates during the electrooxidation process based on unusual electrochemical results. The modification leads formic acid electrooxidation to take place through a desired direct pathway, in which the mechanism is proposed to be the gradual dehydrogenation of formic acid and the reaction of formate with hydroxyl species.

Electrodeposition of platinum nanoclusters on type I collagen modified electrode and its electrocatalytic activity for methanol oxidation

We firstly reported a novel polymer matrix fabricated by type I collagen and polymers, and this matrix can be used as nanoreactors for electrodepositing platinum nanoclusters (PNCs). The type I collagen film has a significant effect on the growth of PNCs. The size of the platinum nanoparticles could be readily tuned by adjusting deposition time, potential and the concentration of electrolyte, which have been verified by field-emitted scanning electron microscopy (FE-SEM). Furthermore, cyclic voltammetry (CV) has demonstrated that the as-prepared PNCs can catalyze methanol directly with higher activity than that prepared on PSS/PDDA film, and with better tolerance to poisoning than the commercial E-TEK catalyst. The collagen-polymer matrix can be used as a general reactor to electrodeposit other metal nanostructures.

Highly efficient electrocatalytic oxidation of formic acid by electrospun carbon nanofiber-supported PtxAu100-x bimetallic electrocatalyst

Electrospun carbon nanofiber-supported bimetallic PtxAu100-x electrocatalysts (PtxAu100-x/CNF) were prepared by electrochemical codeposition method. The composition of PtAu bimetallic nanoparticles could be controlled by varying the ratio of H2PtCl6 and HAuCl4. Scanning electron microscopy images showed that bimetallic nanoparticles had coarse surface morphology with high electrochemically active surface areas. X-ray diffraction analysis testified the formation of PtAu alloys. PtxAu100-x/CNF electrocatalysts exhibited improved electrocatalytic activities towards formic acid oxidation by providing the selectivity of the reaction via dehydrogenation pathway and suppressing the formation/adsorption of poisoning CO intermediate, indicating that PtxAu100-x/CNF is promising electrocatalyst in direct formic acid fuel cells.