中国有色金属学报
ZHONGGUO YOUSEJINSHU XUEBAO
第18卷 第11期 总第116期 2008年11月 |
[PDF全文下载]
文章编号:1004-0609(2008)11-2044-06
碳载Pd-Co-Au合金纳米粒子的制备及其电催化性能
王文明1, 2,李晓伟1,邹志清1,袁 婷1, 杜 翀1,夏保佳1,杨 辉1
(1. 中国科学院 上海微系统与信息技术研究所,上海 200050;
2. 湖南省电力勘测设计院,长沙 410007)
摘 要: 采用乙二醇还原法并进一步热处理制备碳载Pd-Co-Au (Pd-Co-Au/C)三元合金纳米电催化剂,通过旋转圆盘和环盘电极等技术评价催化剂对氧气还原反应的电催化活性,并分析氧气还原的机理。结果表明:合成Pd-Co-Au/C催化剂中Pd和Au两相面心立方(fcc)结构共存,且随着热处理温度的提高,对应于Au的衍射峰强度减弱,而Pd衍射峰强度增强;当温度高于800 ℃时,形成具有Pd单相fcc结构的三元合金纳米催化剂。氧气还原反应的动力学表明:氧气在Pd-Co-Au/C三元合金催化剂上按4e路径还原为水。电化学表征表明,在酸性介质中,经800 ℃热处理的Pd7Co2Au1/C催化剂对氧气还原的电催化活性最高,接近于商业化Pt/C的性能;而在含甲醇的酸性介质中,Pd-Co-Au/C催化剂电催化氧气还原的活性显著高于Pt/C。因此,Pd-Co-Au/C是一种高抗甲醇的新型氧气还原反应电催化剂。
关键字: Pd合金;纳米粒子;氧还原反应;电催化;抗甲醇
Preparation and electrocatalysis of carbon-supported Pd-Co-Au ternary alloy nanoparticles
WANG Wen-ming1, 2, LI Xiao-wei1, ZOU Zhi-qing1, YUAN Ting1, DU Chong1, XIA Bao-jia1, YANG Hui1
(1. Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences,Shanghai 200050, China;
2. Hunan Electric Power Design Institute, Changsha 410007, China)
Abstract:Carbon-supported Pd-Co-Au ternary alloy nanoparticle electrocatalysts were prepared by modified polyol reduction, and then heat-treated at 500−900 ℃. The electrocatalytic activities for the oxygen reduction reaction (ORR) were investigated based on porous rotating disk and disk-ring electrode techniques. The results show that the as-prepared Pd-Co-Au/C catalysts have broad reflections corresponding to the mixed Au and Pd face centred cubic (fcc) phases and the intensity of Au-rich phase relative to Pd-rich phase decreases with the increase of heat treatment temperature. When the heat treatment temperature is higher than 800 ℃, Pd ternary alloys with Pd fcc structure form. The electrochemical measurements indicate that the maximum catalytic activity for the ORR is found on the Pd7Co2Au1/C catalyst heat-treated at 800 ℃, which is close to the commercially available Pt/C. Kinetic analysis reveals that the ORR on Pd-Co-Au/C undergoes a four-electron process to water. Since Pd-Co-Au/C catalysts are inactive for the adsorption and oxidation of methanol, thus, they can be used as a new type of promising catalyst for methanol-tolerant ORR in a direct methanol fuel cell.
Key words: Pd alloy; nanoparticle; oxygen reduction reaction; electrocatalysis; methanol tolerance