Pt纳米晶上CO电吸附及电氧化的表面增强红外吸收光谱研究

为理解Pt 纳米晶(NCs)表面上吸附与反应的结构效应, 本文利用电化学衰减全反射-表面增强红外吸收光谱(ATR-SEIRAS)初步研究了{100}优先取向的Pt 纳米晶表面CO电吸附和电氧化. 合成并清洗过的Pt 纳米晶在硫酸溶液中的循环伏安图出现了四对氧化还原峰, 其中位于0.26和0.36 V的峰分别对应于短程有序和长程有序Pt{100}上的氢吸脱附. 利用Bi、Ge 不可逆吸附法估算出Pt{100}和Pt{111}纳米晶筹分别占34% 和17%. 在原位红外光谱研究中, 首次分辨出线性吸附的CO (CO_L)物种在Pt 纳米晶的三个基础小晶面上的振动谱峰. 动电位光谱分析结果表明Pt{110}上吸附的CO_L优先电氧化, 其次{111}上的CO_L发生氧化, 而Pt{100}上CO_L氧化过电位最高.     

Pt(110)/Sb电极上甲酸的电催化氧化特征和动力学

研究了Sb在Pt(110)晶面上不可逆吸附电化学特性及甲酸在Sb_ad修饰Pt(110)电极[Pt(110)/Sb]上的电催化氧化特征及其反应动力学.发现当扫描电位的上限E_u≤0.45V时,Sb_ad可稳定地吸附在Pt(110)表面上,从而有效地抑制了甲酸的解离吸附.与未修饰的Pt(110)上的结果相比,在Pt(110)/Sb上甲酸氧化的峰电位负移了0.35V.当θ_Sb=0.126时,Pt(110)/Sb电极对甲酸的电催化活性最高.还研究了Pt(110)/Sb上甲酸氧化反应的动力学,定量解析了不同θ_Sb下甲酸氧化的速度常数kf和传递系数β.     

研究表面扩散的双电解池方法及其在铂钌二元金属电催化研究中的应用

本文介绍一种由各自质子交换膜(作为电解质),参比电极和对电极在同一个工作电极上建立两个空间分离的、可独立控制的双电解池系统.它能够由第1个恒电位仪控制的第1电解池的工作电极产生某种吸附中间物,该中间物通过表面扩散到达第2个电解池的工作电极后,在第2个恒电位仪的控制下得到电化学检验.应用这一装置测量了铂电极上欠电势沉积的含氧吸附物种的表面扩散系数,并研究模拟铂钌电极电氧化有机小分子产生的毒性中间物与表面含氧吸附物种的相互作用.在质子交换膜燃料电池的燃料极的工作电势下,没有发现钌表面产生的含氧吸附物种扩散到铂的表面.作者据此假设Pt Ru协同催化作用的实现可能是由于铂上毒性中间物的表面扩散速率非常慢,限制了向钌表面的溢流速率.只有当Pt Ru边界足够大,中间物在铂表面扩散途径非常短时才能形成足够的流速,并在钌表面被表面含氧物种氧化成CO2,使铂表面被重新活化.     

甲酸在Nd-Fe-WO2-4氰桥混配物修饰铂电极上的电催化氧化

首次用电沉积法制备了Nd-Fe-WO2-4氰桥混配物修饰铂电极(Nd-Fe-WO2-4/Pt),并通过SEM和XRD技术分别表征了该修饰电极的表面形貌和修饰物的晶相结构.采用循环伏安法和计时电流法研究了甲酸在该修饰电极上的电氧化行为,实验发现甲酸在修饰电极上的电催化氧化电流密度与裸铂电极相比增加了10余倍,而且CV回扫...     

在LiCl-KCl-NaCl熔盐体系中碳的阴极还原的研究

用循环伏安法和电位阶跃法研究了LiCl-KCl-NaCl熔盐体系中碳的阴极还原机理。在钨、铂、不锈钢等微电极上得到的伏安图表明碳的还原是由CO_3~(2-)离子经一步电化学反应实现的,电极反应速度控制步骤为CO_3~(2-)离子向阴极的扩散过程,还原过程具有反应物吸附特征。碳在W、Pt、不锈钢电极上析出电位分别为-2.05V、-1.745V和-1.90V(均相对于Ag/AgCl参比电极)。     

吸附原子电催化机理的研究——铂单晶(100)晶面上Pb、Cd吸附原子在甲酸电氧化中的助催化特性

七十年代以来,大量文献报道了某些金属原子的欠电位吸附(UPD)对电催化剂特性的影响.一个典型的例子是甲酸氧化中Pt电极上Pb~(2+)的UPD可增强电催化活性.已知甲酸在铂电极上可经两条平行途径氧化至CO_2,     

甲酸在纳米金承载铂(Pt^Au)电催化剂上的电化学氧化

采用循环伏安扫描测试对不同浓度的甲酸在纳米Au颗粒((10.0±1.2)nm)承载Pt电催化剂(记为Ptm^Au,其中m为Pt/Au原子比)上的电化学氧化过程进行了研究.结果表明,Pt在纳米Au颗粒表面的形态对甲酸的电化学氧化行为影响显著.当Pt对Au颗粒形成壳层覆盖(m>0.2)时,甲酸电氧化反应主要发生在高电势(相对SCE电极为0.6~1.0 V)范围,与常规Pt/C电催化剂上甲酸的电氧化行为类似;当Au表面Pt的形态由单原子壳层(m=0.2)递变为不大于1.0 nm的Pt原子簇或原子筏(m<0.2)时,在低电势(-0.2~0.6 V)范围也能明显检测到甲酸的电氧化反应,而且随着m的减小,Pt的质量比活性显著提高.Pt呈现100%暴露(电化学活性面积EAS=236 m2/g-Pt)的Pt0.05^Au/C电催化剂在甲酸电氧化峰(0.38 V)处的质量比活性是通常Pt/C电催化剂(Pt分散度为30%或EAS为74 m2/g-Pt)的40倍,表明随着Au颗粒上Pt尺寸的减小或分散度的提高,Ptm^Au/C电催化剂对甲酸电氧化反应的催化活性也显著提高.在甲酸浓度由0.2 mol/L渐提高至3.2 mol/L时,Ptm^Au/C和Pt/C催化剂上甲酸电氧化反应的比电流均呈先增大后减小的火山形变化,表明适宜的甲酸工作浓度也是在Pt基催化剂上实现高功率直接甲酸燃料电池的关键因素之一.     

自组装纳米金膜上铂微/纳结构电催化剂的制备及性能

基于纳米金(AuNP)表面基团的静电自组装作用制备了多层有序的纳米金超薄膜. 研究了自组装纳米金超薄膜上铂微/纳结构催化剂(Pt/AuNP)的制备过程. 考察了沉积电位和沉积时间对甲酸电氧化活性的影响, 确定了最佳沉积电位为0 V, 最佳沉积时间为600 s. 同时对比考察了Pt/AuNP/PE/GCE, AuNP/PE/GCE和纯Pt电极在0.1 mol/L H2SO4介质中对甲酸电氧化活性以及载体对沉积物形态和甲酸氧化活性的影响. 研究结果表明, 纳米金组装体对铂的电沉积有明显的促进作用; Pt/AuNP/PE/GCE对甲酸的电氧化有很好的电催化性能.     

一种提高铂电催化氧化甲酸性能的简单方法

在离子液体1-乙基咪唑三氟乙酸盐(HElmTfa)中,采用循环伏安法在铂电极表面修饰聚吡咯(PPY),制得PPy-HEImTfa/Pt,并研究了其对甲酸的电催化氧化性能.与相同条件下的铂基底电极相比,PPy-HEImTfa/Pt对甲酸的电催化氧化性能有很大的提高.原位红外光谱表明,PPy-HElmTfa能降低中间体CO等对铂电极的毒化作用,促进甲酸直接氧化生成CO_2.     

UPD铅对甲酸在铂上电氧化的助催化功用的研究

应用电位扫描和电位-时间程序技术研究了在UPD铅不存在和存在的情况下,各种因素对甲酸在铂上和酸介质中电催化氧化的影响。结果表明,在甲酸的CV图上,阳极方向的第一氧化峰和阴极方向的氧化峰是由于同一的弱吸附中间物的氧化,而阳极方向的第二和第三氧化峰是由于两种不同的强吸附中间物的氧化。cps值的测定和电极表面宏观结构的影响等实验表明,这些吸附中间物在电极表面上都呈线性吸附,它们分别可能是单键吸附的HCOO_ad双键吸附的CO_ad和叁键吸附的COH_ad。据此可以推论,UPD铅的主要功用是一种电子效应。     

甲酸在Aucore@Ptshell/Pt电极上电催化氧化的原位SERS

用化学还原法合成了Aucore@Ptshell纳米粒子, 并用扫描电子显微镜(SEM)及X射线衍射(XRD)等技术对纳米粒子进行表征; 采用电化学原位表面增强拉曼光谱(SERS)技术对甲酸的电催化氧化过程进行了研究, 成功地获得了甲酸在Aucore@Ptshell/Pt电极上解离吸附的原位SERS. 结果显示, 在开路电位时, 甲酸能在Aucore@Ptshell/Pt电极表面自发氧化, 解离生成强吸附中间体COad和弱吸附中间体HCOOad, 在电位为+0.10 V时检测到氧化产物CO2的谱峰. 研究结果表明, Aucore@Ptshell/Pt电极对甲酸的氧化具有较高的催化活性和较强的SERS效应, 甲酸在Aucore@Ptshell/Pt电极上的电催化氧化过程遵循双途径机理.     

STUDIES ON PROMOTION OF UPD OF. LEAD FOR ELECTRO-OXIDATION OF FORMIC ACID ON PLATINUM

Using potential sweep and potential-time sequence techniques,we have studied the promotion of the UPD of lead for the electrocata-lytic oxidation of formic aeid on platinum in the HClO4 aqueous solution.The results show that the first oxidation peak in the anodic direction and the oxidation peak in the cathodic direction in the cyclic voitammogram are attributed to the oxid-ation of the same weakly adsorbed intermediate,while the second and third oxidation peaks in the anodic direction are attributed to the oxidation of the two different strongly adsorbed intermediates.Furthermore,all these intermediates appear as the linear adsorption on the platinum surface and they are probably single bonded species,Pt-HCOO,and multiple bonded species,Pt=CO and Pt=COH,respectively.So the function of the UPD of lead for the electro-oxidation of formic acid is neither a third-body effect nor the decrease of nydrogen adsorption thus preventing the formation of poisoning species.The role of the UPD of lead should be an e     

Formic acid oxidation at platinized platinum electrodes: Part II. Effect of temperature on steady state oxidation process

A study has been made of the effect of temperature on the steady state oxidation of formic acid on platinized platinum electrodes in 0.5 M HCOOH+0.5 M H₂SO₄. The activation energy and entropy of activation for the anodic oxidation process decrease sharply with increase in electrode potential. The results provide additional evidence that the weakly adsorbed intermediate pathway proceeds through a rate-determining step involving the dissociation of weakly adsorbed formic acid molecule.     

粗糙铂电极上甲酸吸附氧化的电化学原位表面增强拉曼光谱研究

采用循环伏安法和电化学原位表面增强拉曼光谱（SERS）技术研究甲酸的解离 及附与氧化行为。首次报道了甲酸吸附、解离和氧化的电化学原位SERS谱，发现甲 酸在粗糙铂电极上能自发解离吸附；首欠成功地获得了粗糙铂电极上甲酸吸附解离 的强吸附中间体CO和活性中间体COOH的表面增强拉曼光谱，同时首次检测到甲酸氧 化最终产物CO_2的拉曼光谱信号，从分子水平证实甲酸解离吸附反应的双途径机理 。     

Towards Mixed Fuels: The Electrochemistry of Hydrazine in the Presence of Methanol and Formic Acid

The electrochemistry of formic acid, carbon monoxide and methanol have been investigated and evaluated in combination with hydrazine. Hydrazine was observed to display the anticipated steady‐state oxidation waves at platinum (Pt) microelectrodes by cyclic voltammetry, and upon introduction of carbon monoxide (CO) gas, the Pt surface was fully passivated (prior to CO oxidation). However, the two individual responses of hydrazine and formic acid (HCOOH) are to be additive when combined in solution. No detrimental effects were observed upon the hydrazine voltammetry, even in the presence of excess formic acid, despite formic acid clearly displaying characteristic self‐poisoning tendencies (primarily due to the formation of CO) in its own voltammetry. Effects intermediate to those of CO and formic acid were observed when methanol was present. Currents were essentially additive at low methanol content, but hydrazine oxidation current decreased by about 40 % when an 100‐fold excess of methanol was present, corresponding to poisoning by methanol dehydrogenation intermediates. These results are discussed with relevance to mixed fuels for more flexible or powerful fuel cells, and the possible formation of a random microelectrode array (templated by strongly adsorbed poison) on the microelectrode surface.     

Adsorbed intermediates of formaldehyde oxidation and their role in the reaction mechanism

Formaldehyde oxidation was studied on the basal planes of platinum single crystals. Electrochemical and IR spectroscopy data give new information on the mechanism of oxidation. Formaldehyde oxidation at platinum electrodes is a surface-sensitive reaction. From the three basal planes of Pt(hkl), Pt(111) is the most active one. The less active surfaces Pt(100) and Pt(110) are blocked by adsorbed carbon monoxide at the initial stages of the reaction as the formaldehyde is admitted in the solution with the electrode polarized at 0.05 V. Besides CO(ad), other adsorbed species are formed. From these, methylene glycolate, H2COO(ad), is the intermediate of the fast oxidation pathways forming CO2 and HCOOH as soluble products. According to IR data the yields of soluble products at Pt(111) were calculated at 0.6 V, giving 63% for HCOOH and 37% for CO2. At 0.05 V the Pt(111) surface becomes slowly blocked by CO(ad), as observed when the electrode was left in contact with the formaldehyde solution over a period of several minutes. The same blockage occurs during a cyclic voltammogram, which causes a lowering of activity during the second potential scan. A general scheme of the reaction is proposed.     

Cyclic Voltammetric and Morphological Studies of Polyaniline

Cyclic voltammograms and morphology of polyaniline were studied under various synthetic conditions and in various protonic acid media. The effect of protonic acid is not remarkable. The cyclic voltammogram and morphology depend on the synthetic conditions. The anodic peak potential at 0.14 V versus SCE in the cyclic voltammogram is pH independent. The anodic peak potential at 0.7 V versus SCE (pH=1) is pH dependent. By comparing the range of pH and oxidation potential of the conductive form, we propose that the conductive species which exists in the potential range between the first and the second peak in cyclic voltammogram is the radical cation.     

Kinetics of dissociative adsorption of formic acid on electrodes of tetrahexahedral platinum nanocrystals

In the present paper we study the kinetics of dissociative adsorption of formic acid on the electrode of tetrahexahedral platinum nanocrystals (THH Pt NCs). In situ FTIR spectroscopic results demonstrate that HCOOH can be oxidized to CO2 at a low potential (-0.2 V(SCE)) on the THH Pt NCs electrode, and the chemical bonds inside formic acid molecule are broken to form adsorbed COL species. The kinetics of the dissociative adsorption of HCOOH was quantitatively investigated by employing programmed potential s...     

甲酸在钼青铜修饰铂电极上的催化氧化

应用循环伏安法和双电位阶跃法研究了不同浓度硫酸中钼酸盐在多晶铂电极上的电化学行为 .在硫酸溶液中 ,当电位负向扫描时 ,钼酸盐即于铂电极上还原形成钼青铜 ,吸附在电极表面 ;电位正向扫描时钼青铜将再被氧化 ,氧化机理受硫酸浓度的影响 .铂电极因钼酸盐的还原和钼青铜的氧化而得到修饰 .在硫酸钠溶液中以此修饰的铂电极对甲酸氧化有明显的催化作用 ,其氧化峰电流接近未修饰铂电极上的 2倍 .钼青铜对铂的不完全修饰或过分修饰均会减弱甲酸氧化的催化作用