表面富Pd的Ni-Pd/C催化剂的合成及电化学性质研究

应用改进的多元醇法,分步还原制备表面富Pd的N iPd双元合金催化剂.研究表明:由于Pd较容易还原成核,且与N i的合金化程度低,Pd难以在N i颗粒表面实现单层包覆形成N i@Pd核壳结构,而是近似以单相的低合金化形式存在于N i颗粒表面,即形成N i@Pd(N i)的结构.与Pd/C相比,制备的N i@Pd(N i)/C催化剂,其Pd表面的氢吸附峰与吸收峰分辨清晰,含氧化物的脱附峰向正电势移动,氧还原活性显著提高.另外,N i的存在使Pd的抗甲醇性能明显增强,从而有望作为直接甲醇燃料电池的阴极催化剂.     

Pd组分的添加对Ni-B非晶态合金催化剂顺酐选择加氢制γ-丁内酯反应的影响

采用化学还原法制备了用于顺酐加氢的Pd-N i-B非晶态催化剂,考察了Pd含量,反应温度,反应时间对催化剂性能的影响;利用XRD,TEM,XPS,ICP等手段对催化剂进行了表征.结果发现,添加适量的Pd可以明显改善催化剂的加氢性能,在N i-Pd-B-3催化剂上,顺酐的转化率为100%,γ-丁内酯的收率为89.6%.催化剂中N i具有给电子效应,使Pd的表面呈富电子状态,有利于原料的吸附和产物的脱附.     

Pd-Cu/C上甲酸根电催化氧化及其去合金化效应

以柠檬酸钠为稳定剂,通过一锅法在乙二醇体系中制得高分散的Pd-Cu/C二元合金催化剂. 用高分辨透射电镜和XRD观察、表征其形貌和结构,经重复循环扫描对Pd-Cu/C催化剂进行去合金化处理,研究了去合金效应对甲酸根电催化氧化性能的影响. 通过吸附CO的原位ATR-IR光谱测量,初步探讨了去合金前后催化剂表面结构的改变. 研究表明,Cu的去合金化可提高Pd-Cu/C电极初始的电催化氧化活性,但不利于其长时间的活性保持;合金化Pd-Cu/C电极电催化稳定性有显著的优势.     

电化学去合金化Pt(Pd)-Cu对氧的电催化还原活性的研究

应用电化学去合金法制备了表面覆盖有Pt(Pd)原子层的Pt(Pd)-Cu合金催化剂.研究该催化剂在0.1mol.L-1HClO4酸性溶液中对氧气电化学还原的催化活性,并采用同步辐射反常X-射线衍射法(Anomalous X-ray Diffraction,AXRD)和表面X-射线散射法(Surface X-ray Scattering,SXS)从原子尺度研究了去合金化后催化剂的结构.分析对比纳米颗粒、薄膜和单晶3种不同形式的去合金化Pt-Cu的结构和催化活性以及Pt-Cu和Pd-Cu两种不同合金薄膜的结构和催化活性.结果表明,表面应力是影响催化剂催化活性的关键因素,而应力大小则与去合金化后所形成的表面Pt(Pd)层的厚度相关,材料尺寸和组成元素等都影响表面Pt(Pd)层的厚度.提出可利用调控材料表面的应力来设计高催化活性的催化剂.     

纳米孔金膜电极：合金化/去合金化法制备及电化学性能

采用合金化/去合金化法在金电极表面制备出一层具有纳米孔结构的金膜，其孔径约为15 nm。该方法首先在金电极表面电沉积一层锌，再通过热处理形成合金层，最后利用化学去合金化法去除合金中的锌。X射线衍射(XRD)结果表明在合金化过程中，锌扩散进入金基体并形成了金-锌合金层。利用场发射扫描电子显微镜(FESEM)对去合金化得到的纳米孔金膜进行了形貌的表征，结果表明合金化条件对样品的纳米结构有明显的影响。电化学测试结果表明，经合金化/去合金化处理的金电极，其表面粗糙度有明显的提高。这种金电极对甲醇具有较高的催化氧化活性，在0.3 mol·L^-1甲醇的KOH溶液中，甲醇的氧化峰电流密度高达2.02 mA·cm^-2。     

La_(0.7)Pr_(0.15)Nd_(0.05)Mg_(0.3)Ni_(3.3-x)Co_(0.2)Al_(0.1)(Co_(0.75)Mn_(0.25))_x(x=0.0,0.2,0.4,0.6)的电化学性能研究

在Ar气保护下用悬浮熔炼制备La0.7Pr0.15Nd0.05Mg0.3N i3.3-xCo0.2A l0.1(Co0.75Mn0.25)x(x=0.0,0.2,0.4,0.6)合金,系统研究了Co和Mn对合金储氢性能和电化学性能的影响。XRD相分析表明,合金相主要由(La,Pr)(N i,Co)5,LaMg2N i9,(La,Nd)2N i7和LaN i3相组成;添加Co和Mn后合金中(La,Pr)(N i,Co)5,(La,Nd)2N i7和LaN i3相晶胞体积增加,LaMg2N i9相晶胞体积变小。合金放氢PCT曲线测试表明,随着合金中Co和Mn含量的增加,合金吸氢量先减小后增加,放氢平台压下降,合金氢化物稳定性增加。合金电极电化学性能测试表明,添加Co和Mn使合金电极放电容量减小,容量保持率S100从53.2%(x=0.0)增加到63.0%(x=0.6),合金电极的电循环稳定性增强,高倍率放电性能HRD1500先增加后减小。此外,合金电极的极化电阻先减小后增加,交换电流密度、循环伏安特性阳极峰电流密度和极限电流密度先增加后减小,合金内氢原子扩散系数先增加后减小,表明添加适量的Co和Mn可以提高合金电...     

LaMg_(11)Zr+Ni合金电极电化学性能研究

以LaMg11Zr为母体合金,由机械合金化方法制备LaMg11Zr+200%N i合金,用X射线衍射(XRD)测定球磨时间对非晶相化的影响,20 h合金即可达到完全非晶态化,合金电极化学性能和循环寿命最好.     

高透量 PdAu/陶瓷复合膜的表征与性能评测

 采用化学镀方法在非对称氧化铝管状载体上制备出高性能 PdAu 合金膜. 采用阶段性热处理方法通过 X 射线衍射技术监测 PdAu 膜层合金化进程, 发现在 823 K 下 H2 气氛中厚度为 2 μm, Au 含量为 17.37% 的 PdAu 双金属膜层需要 200 h 达到完全合金化; N2/H2 气氛对 PdAu 合金化速率无显著影响, 但 N2 气氛中合金化后的 PdAu 合金膜表面粒子烧结更为严重. 在 623~823 K 下, 与未进行化学镀 Au 时的纯 Pd 膜相比, PdAu 合金膜的 H2 渗透速率平均增加 1.68 倍, 透氢活化能 (Ea) 降低 38.51%; 当温度低于 573 K 时, PdAu 合金膜的 Ea 由高温时的 8.83 kJ/mol 增加到 15.75 kJ/mol, 此时 PdAu 合金膜的 H2 渗透控速步骤由体相扩散为主的 H2 传质步骤过渡到由表面扩散为主的传质步骤. 通过扫描电镜和能谱联用仪对 PdAu 合金膜的膜厚度和截面组成进行了表征. 关键词     

钆对La-Mg-Ni系A_2B_7型储氢合金微观结构和电化学性能的影响

用高频感应熔炼方法制备了稀土系A2B7型La0.83-xGdxMg0.17N i3.05Co0.3A l0.15(x=0~0.5)储氢合金,在Ar气氛中和1173 K下对铸态合金进行退火处理,通过X射线衍射(XRD)、电子探针显微分析方法(EPMA)和电化学测试等分析方法系统研究了稀土Gd部分替代La元素对合金微观组织和电化学性能的影响规律。研究结果表明,合金退火组织主要由Ce2N i7型、Gd2Co7型、Pr5Co19型、PuN i3型和CaCu5型相组成,稀土Gd元素能有效减少和抑制退火组织中CaCu5型相的形成,随Gd含量x增加,合金相组成中A2B7型(Ce2N i7和Gd2Co7型)相丰度呈先增加后减小的规律,当x=0.2时其相丰度最大(91.0%)。合金的PCT吸氢平台压随Gd含量的增加而升高,x=0.5时吸氢平台压力接近0.1 MPa,x=0.2时合金的吸氢量达到最大值1.34%。电化学测试分析表明,随Gd含量x的增加,合金电极最大放电容量和容量保持率均呈先增加后减小的规律,适量的Gd元素可明显改善合金的综合电化学性能。当x=0.2时,合金电极放电容量达到最大值392.9 mAh.g-1,经100...     

Mg0.9－xTi0.1PdxNi(x=0.04～0.1)贮氢合金电极腐蚀行为研究

研究了Pd部分替代Mg对Mg0.9－xTi0.1PdxNi(x=0.04～0.1)贮氢合金腐蚀性能的影响. 利用机械合金化方法制备了Mg0.9－xTi0.1PdxNi(x=0.04～0.1)贮氢合金. XRD和TEM分析表明经120 h球磨后该合金完全非晶化. 循环充放电测试结果表明, Pd的替代有效地延长了Mg0.9－xTi0.1PdxNi(x=0.04～0.1)合金的循环寿命. 采用开路电位测量, 阳极极化, 电化学阻抗和X射线光电子能谱研究了该合金的腐蚀行为. 结果表明, 随着Pd含量增加, 合金腐蚀电位正移, 初始腐蚀电流下降, 腐蚀电流增加的速度变缓. 采用本文提出的等效电路模型较好地拟合了合金的电化学阻抗谱. 分析表明, 随着Pd含量的增加, 合金表面钝化膜厚度和电阻逐渐增大. X射线光电子能谱分析表明, Pd的加入减弱了合金在充放电过程中的氧化程度. 当Pd含量达到0.1时, Mg0.9－xTi0.1PdxNi(x=0.04～0.1)合金的耐腐蚀性能最好, 其放电容量保持率最高.     

Hydrogen transport through Pd-Ni alloy electrodeposited on Pd substrate

Hydrogen transport through a Pd-Ni alloy electrodeposited on a Pd substrate (Pd-Ni/Pd bilayer symmetric electrode) has been investigated using cyclic voltammetry and a.c. impedance spectroscopy combined with the electrochemical hydrogen permeation method. The permeation build-up current transients and the measured impedance spectra were analyzed using the time-lag method for the bilayer electrode and a complex non-linear least squares data-fitting method based upon the derived Faradaic admittance for the hydrogen absorption into and diffusion through the bilayer electrode under the permeable boundary condition, respectively. The value of the hydrogen diffusivity in the Pd-Ni layer was lower than that in the Pd layer. Furthermore, the values of the charge transfer resistance and equilibrium absorption constant for the Pd-Ni/Pd bilayer electrode were higher than those for the Pd single layer electrode. From the experimental results, the role of the thin Ni(OH)₂ film formed on the Pd-Ni layer surface in the hydrogen transport through the Pd-Ni/Pd bilayer electrode is discussed in terms of its passivating effect and extremely large hydrogen solubility. Received: 22 January 1997 / Accepted: 15 April 1997     

Electroanalysis of tetracycline using nickel-implanted boron-doped diamond thin film electrode applied to flow injection system.

The electrochemical analysis of tetracycline was investigated using nickel-implanted boron-doped diamond thin film electrode by cyclic voltammetry and amperometry with a flow injection system. Cyclic voltammetry was used to study the electrochemical oxidation of tetracycline. Comparison experiments were carried out using as-deposited boron-doped diamond thin film electrode (BDD). Nickel-implanted boron-doped diamond thin film electrode (Ni-DIA) provided well-resolved oxidation irreversible cyclic voltammograms. The current signals were higher than those obtained using the as-deposited BDD electrode. Results using nickel-implanted boron-doped diamond thin film electrode in flow injection system coupled with amperometric detection are presented. The optimum potential for tetracycline was 1.55 V versus Ag/AgCl. The linear range of 1.0 to 100 microM and the detection limit of 10 nM were obtained. In addition, the application for drug formulation was also investigated.     

Preparation and electrochemistry of Pd-Ni/Si nanowire nanocomposite catalytic anode for direct ethanol fuel cell

A new silicon-based anode suitable for direct ethanol fuel cells (DEFCs) is described. Pd-Ni nanoparticles are coated on Si nanowires (SiNWs) by electroless co-plating to form the catalytic materials. The electrocatalytic properties of the SiNWs and ethanol oxidation on the Pd-Ni catalyst (Pd-Ni/SiNWs) are investigated electrochemically. The effects of temperature and working potential limit in the anodic direction on ethanol oxidation are studied by cyclic voltammetry. The Pd-Ni/SiNWs electrode exhibits higher electrocatalytic activity and better long-term stability in an alkaline solution. It also yields a larger current density and negative onset potential thus boding well for its application to fuel cells.     

Ru膜上Pt层的自发沉积及其在电化学表面增强红外光谱中的应用

采用自发沉积法在Ru膜上生成超薄Pt层(简称Ru/Pt膜), 即在开路状态下将电化学还原后的Ru膜浸于除去氧的H2PtCl6溶液中进行自发沉积. 电化学伏安法测量表明, 随着电还原-自发沉积循环次数的增加, 该Ru/Pt膜电极所含Pt组分增加, 且CO吸附层的电氧化峰电位较Pt膜电极上的明显负移. 应用现场衰减全反射表面增强红外光谱法(ATR-SEIRAS)可轻易检测到在该膜电极Pt和Ru位上吸附CO的振动谱峰. 所制Ru/Pt膜电极不仅对CO的电催化氧化具有协同效应, 还可应用于现场ATR-SEIRAS的研究中.     

碱性介质中多孔纳米结构镍/钯-镍电极上甲醇电氧化反应(英文)

A nanostructured Ni/Pd-Ni catalyst with high activity for methanol oxidation in alkaline solution was prepared by electrodeposition followed by galvanic replacement, that is, electrodeposition of Ni-Zn on a Ni coating with subsequent replacement of the Zn by Pd at the open circuit potential in a Pd-containing alkaline solution. The surface morphology and composition of the coatings were examined by energy dispersive X-ray spectroscopy and scanning electron microscopy. The Ni/Pd-Ni coatings were porous and were composed of discrete Pd nanoparticles of about 58 nm. The electrocatalytic activity of the Ni/Pd-Ni electrodes for the oxidation of methanol was examined by cyclic voltammetry and electrochemical impedance spectroscopy. The onset potentials for methanol oxidation on Ni/Pd-Ni were 0.077 V and 0.884 V, which were lower than those for flat Pd and smooth Ni electrodes, respectively. The anodic peak current densities of these electrodes were 4.33 and 8.34 times higher than those of flat Pd (58.4 mA/cm2 vs 13.47 mA/cm2) and smooth Ni (58.4 mA/cm2 vs 7 mA/cm2). The nanostructured Ni/Pd-Ni electrode is a promising catalyst for methanol oxidation in alkaline media for fuel cell application.     

炭载Pd-Ni合金纳米粒子对甲酸的电催化氧化

通过液相还原法制备了具有不同原子比例的Pd-Ni/C催化剂,并且使用X射线衍射（XRD）、透射电子显微镜(TEM)和X射线光电子能谱(XPS) 等表征手段对制备的催化剂进行了表征,总结了Ni的掺杂对Pd-Ni合金纳米粒子的尺寸及晶体结构的影响。电化学测试结果表明：适量的Ni的掺杂不但能够增强催化剂对甲酸催化氧化的活性,而且还能够提高催化剂的稳定性。因此,Pd-Ni/C催化剂是一类具有潜在应用前景的直接甲酸燃料电池阳极催化剂     

Pulsed amperometric detection of underivatized amino acids using polypyrrole modified copper electrode in acidic solution

The successful pulsed amperometric detection of underivatized amino acids have been carried out in an acidic media on a polypyrrole (PPy) modified Cu electrode. The formation of PPy film doped with glutamate (glu) on a Cu electrode surface changes the mechanism of Cu dissolution. After application of multistep potential waveform, the PPy film was glu free due to the electro-reduction and overoxidation. High anodic potential polarization treatment yielded partially overoxidized PPy film as long as the Cu surface dissolution and amino acid permeation through the film was well controlled. This overoxidized PPy film acted as a charge and size exclusion barrier in order to improve the selectivity and stability of a Cu electrode. Various process parameters such as film modification time, detection and cleaning potential and pH of solution have been optimized to maximize the beneficial electrocatalytic properties of the electrode surface. At an optimized condition, detection limits for positively charged histidine and arginine are 19 and 22 pg respectively, whereas the neutral amino acids detected in amounts of 0.9–2.3 ng. Furthermore, the PPy coated Cu electrode response was long lived, stable and reproducible.     

Electropreparation of Poly(benzophenone‐4) Film Modified Electrode and Its Electrocatalytic Behavior Towards Dopamine,Ascorbic Acid and Nitrite

The oxidation of benzophenone‐4 (2‐hydroxy‐4‐methoxybenzophenone‐5‐sulfonic acid) at glassy carbon electrode gives rise to stable redox active electropolymerized film during repetitive potential cycling between 0 to 1.3 V (Ag/AgCl). Cyclic voltammogram of poly(benzophenone‐4) film shows a redox couple with well‐defined peaks. The redox response of the modified electrode was found to be depending on the pH of the contacting solution. The peak potentials were shifted to a less positive region with increasing pH and the dependence of the peak potential was found to be 51 mV/pH. The electrocatalytic behavior of poly(benzophenone‐4) film modified electrode towards oxidation of dopamine, ascorbic acid and reduction of nitrite was investigated. The oxidation of dopamine and ascorbic acid occurred at less positive potential on poly(benzophenone‐4) film compared to bare glassy carbon electrode. For dopamine, the overpotential was reduced about 180 mV. Feasibility of utilizing poly(benzophenone‐4) film coated electrode in analytical estimation of dopamine, ascorbic acid and nitrite was also demonstrated.     

Effect of ex situ hydrogenation on the structure and electrochemical properties of amorphous silicon thin film

Nickel-metal hydride (Ni-MH) batteries were widely used due to their various advantages, but its further application and development have been seriously hindered by the low electrochemical discharge capacity of conventional hydrogen storage alloy electrode. The hydrogenated amorphous silicon (a-Si:H) thin film electrode for Ni-MH battery has been proven to have a dramatic electrochemical capacity. We prepared a-Si:H thin films by a two-step process of rf-sputtering followed by hydrogenation, and investigated the effect of hydrogenation on the structure and electrochemical properties of which as an anode. The maximum discharge capacity of a-Si:H thin film electrode after hydrogenation increases from initial 180 mAh·g⁻¹to 1827 mAh·g⁻¹, which is over tenfold that of as-deposited hydrogen-less a-Si thin film electrode. Then, the preliminary relationships between hydrogen content and electrochemical performance of a-Si:H thin film electrode were analyzed, and several negative factors of electrochemical performance for a-Si:H thin film electrode were proposed.

     

Preparation,Characterization and Electrocatalytic Studies on Copper Complex Dye Film Modified Electrodes

Copper complex dye (C.I. Direct Blue 200) film modified electrodes have been prepared by multiple scan cyclic voltammetry. The effect of solution pH and nature of electrode material on film formation was investigated. The optimum pH for copper complex film formation on glassy carbon was found to be 1.5. The mechanism of film formation on ITO seems to be similar to that on GC surface but completely different mechanism followed with gold electrode. Cyclic voltammetric features of our modified electrodes are in consistent with a surface‐confined redox process. The voltammetric response of modified electrode was found to be depending on pH of the contacting solution. UV‐visible spectra show that the nature of copper complex dye is identical in both solution phase and after forming film on electrode. The electrocatalytic behavior of copper complex dye film modified electrode towards oxidation of dopamine, ascorbic acid and reduction of SO₅^2? was investigated. The oxidation of dopamine and ascorbic acid occurred at less positive potential on film electrode compared to bare glassy carbon electrode. Feasibility of utilizing our modified electrode in analytical estimation of dopamine, ascorbic acid was also demonstrated.