欢迎访问《电化学(中英文)》期刊官方网站,今天是

电化学 >

2016 , Vol. 22 >Issue 6: 561 - 569

DOI: https://doi.org/10.13208/j.electrochem.160563

界面电化学近期研究专辑(厦门大学 毛秉伟教授)

燃料电池电极表界面催化氧还原反应的STM研究进展

  • 蔡镇锋 ,
  • 孙兵 ,
  • 江文杰 ,
  • 陈婷 ,
  • 王栋 ,
  • 万立骏
展开
  • 1. 中国科学院化学研究所, 中国科学院分子纳米结构与纳米技术重点实验室, 北京 100190; 2. 中国科学院大学, 北京 100049

收稿日期: 2016-06-01

  修回日期: 2016-07-07

  网络出版日期: 2016-07-21

基金资助

国家自然科学基金项目(21233010, 21373236, 21127901, 21573252)资助

收起

STM Investigation of Oxygen Reduction Reaction on Solid Interface in Fuel Cell

  • CAI Zhen-Feng ,
  • SUN Bing ,
  • JIANG Wen-Jie ,
  • CHEN Ting ,
  • WANG Dong ,
  • WAN Li-Jun
Expand
  • 1. CAS Key Laboratory of Molecular Nanostructure and Nanotechnology, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China; 2. University of Chinese Academy of Sciences, Beijing 100049, China

Received date: 2016-06-01

  Revised date: 2016-07-07

  Online published: 2016-07-21

Fold

摘要

催化氧还原反应的电催化剂是燃料电池的一个重要组成部分. 从分子尺度研究催化氧还原反应中所涉及的表界面反应机理,不仅有利于深入理解催化机理,更有利于指导人们合理地设计新型的电催化剂. 本文结合近年来国内外的研究工作,概述了通过扫描隧道显微镜研究燃料电池内部催化氧还原反应过程中所涉及的表面形貌变化、单分子结构变化、中间体的观测以及反应产物调控等方面最新进展,并展望了该研究领域的发展趋势.

关键词: 燃料电池; 氧还原反应; 扫描隧道显微术

本文引用格式

蔡镇锋 , 孙兵 , 江文杰 , 陈婷 , 王栋 , 万立骏 . 燃料电池电极表界面催化氧还原反应的STM研究进展[J]. 电化学, 2016 , 22(6) : 561 -569 . DOI: 10.13208/j.electrochem.160563

Abstract

An electrocatalyst for oxygen reduction reaction (ORR) is an important component for fuel cells. An investigation at interfacial electrochemical reactions toward ORR at a molecular scale benefits mechanistic understanding as well as rational design of catalysts. Scanning tunneling microscopy (STM) has been proven to be a powerful tool to monitor chemical reactions and to provide in-situ information about the interfacial electrochemical reactions at a molecular level. This review summarizes the recent STM studies in monitoring the interface processes such as morphological changes, molecular changes, reaction intermediates, and oxidation products. The prospects of future development in this field are outlined.

参考文献

1.            Sharaf, O Z & Orhan, M F An overview of fuel cell technology: Fundamentals and applications. Renewable & Sustainable Energy Reviews[J], 2014, 32: 810-853.

2.            Steele, B C H & Heinzel, A Materials for fuel-cell technologies. Nature[J], 2001, 414(6861): 345-352.

3.            Debe, M K Electrocatalyst approaches and challenges for automotive fuel cells. Nature[J], 2012, 486(7401): 43-51.

4.            Badwal, S, Giddey, S, Kulkarni, A et al. Direct ethanol fuel cells for transport and stationary applications–A comprehensive review. Applied Energy[J], 2015, 145: 80-103.

5.            Wang, W, Su, C, Wu, Y et al. Progress in solid oxide fuel cells with nickel-based anodes operating on methane and related fuels. Chemical Reviews[J], 2013, 113(10): 8104-8151.

6.            Wu, G, More, K L, Johnston, C M et al. High-Performance Electrocatalysts for Oxygen Reduction Derived from Polyaniline, Iron, and Cobalt. Science[J], 2011, 332(6028): 443-447.

7.            Cui, C, Gan, L, Heggen, M et al. Compositional segregation in shaped Pt alloy nanoparticles and their structural behaviour during electrocatalysis. Nature Materials[J], 2013, 12(8): 765-771.

8.            Yu, W, Porosoff, M D & Chen, J G Review of Pt-based bimetallic catalysis: from model surfaces to supported catalysts. Chemical Reviews[J], 2012, 112(11): 5780-5817.

9.            Wang, D, Xin, H L, Hovden, R et al. Structurally ordered intermetallic platinum–cobalt core–shell nanoparticles with enhanced activity and stability as oxygen reduction electrocatalysts. Nature Materials[J], 2013, 12(1): 81-87.

10.          Sasaki, K, Naohara, H, Cai, Y et al. CoreProtected Platinum Monolayer Shell HighStability Electrocatalysts for FuelCell Cathodes. Angewandte Chemie International Edition[J], 2010, 49(46): 8602-8607.

11.          Wang, G W, Huang, B, Xiao, L et al. Pt Skin on AuCu Intermetallic Substrate: A Strategy to Maximize Pt Utilization for Fuel Cells. Journal of the American Chemical Society[J], 2014, 136(27): 9643-9649.

12.          Chen, C, Kang, Y J, Huo, Z Y et al. Highly Crystalline Multimetallic Nanoframes with Three-Dimensional Electrocatalytic Surfaces. Science[J], 2014, 343(6177): 1339-1343.

13.          Holewinski, A, Idrobo, J C & Linic, S High-performance Ag-Co alloy catalysts for electrochemical oxygen reduction. Nature Chemistry[J], 2014, 6(9): 828-834.

14.          Kuttiyiel, K A, Sasaki, K, Su, D et al. Gold-promoted structurally ordered intermetallic palladium cobalt nanoparticles for the oxygen reduction reaction. Nature Communications[J], 2014, 5: 8.

15.          Lu, Y Z, Jiang, Y Y, Gao, X H et al. Strongly Coupled Pd Nanotetrahedron/Tungsten Oxide Nanosheet Hybrids with Enhanced Catalytic Activity and Stability as Oxygen Reduction Electrocatalysts. Journal of the American Chemical Society[J], 2014, 136(33): 11687-11697.

16.          Savadogo, O, Lee, K, Oishi, K et al. New palladium alloys catalyst for the oxygen reduction reaction in an acid medium. Electrochemistry Communications[J], 2004, 6(2): 105-109.

17.          Wang, X, Choi, S-I, Roling, L T et al. Palladium-platinum core-shell icosahedra with substantially enhanced activity and durability towards oxygen reduction. Nature Communications[J], 2015, 6: 7594.

18.          Miner, E M, Fukushima, T, Sheberla, D et al. Electrochemical oxygen reduction catalysed by Ni-3(hexaiminotriphenylene)(2). Nature Communications[J], 2016, 7: 7.

19.          Masa, J, Xia, W, Muhler, M et al. On the Role of Metals in Nitrogen-Doped Carbon Electrocatalysts for Oxygen Reduction. Angewandte Chemie-International Edition[J], 2015, 54(35): 10102-10120.

20.          Tang, H J, Yin, H J, Wang, J Y et al. Molecular Architecture of Cobalt Porphyrin Multilayers on Reduced Graphene Oxide Sheets for High-Performance Oxygen Reduction Reaction. Angewandte Chemie-International Edition[J], 2013, 52(21): 5585-5589.

21.          Chung, H T, Won, J H & Zelenay, P Active and stable carbon nanotube/nanoparticle composite electrocatalyst for oxygen reduction. Nature Communications[J], 2013, 4: 5.

22.          Zhao, Y, Nakamura, R, Kamiya, K et al. Nitrogen-doped carbon nanomaterials as non-metal electrocatalysts for water oxidation. Nature Communications[J], 2013, 4: 7.

23.          Feng, J, Liang, Y, Wang, H et al. Engineering manganese oxide/nanocarbon hybrid materials for oxygen reduction electrocatalysis. Nano Research[J], 2012, 5(10): 718-725.

24.          Zhao, A Q, Masa, J, Xia, W et al. Spinel Mn-Co Oxide in N-Doped Carbon Nanotubes as a Bifunctional Electrocatalyst Synthesized by Oxidative Cutting. Journal of the American Chemical Society[J], 2014, 136(21): 7551-7554.

25.          Gorlin, Y & Jaramillo, T F A Bifunctional Nonprecious Metal Catalyst for Oxygen Reduction and Water Oxidation. Journal of the American Chemical Society[J], 2010, 132(39): 13612-13614.

26.          Liang, Y, Li, Y, Wang, H et al. Co3O4 nanocrystals on graphene as a synergistic catalyst for oxygen reduction reaction. Nature Materials[J], 2011, 10(10): 780-786.

27.          Gewirth, A A & Thorum, M S Electroreduction of dioxygen for fuel-cell applications: materials and challenges. Inorganic Chemistry[J], 2010, 49(8): 3557-3566.

28.          Sedona, F, Di Marino, M, Forrer, D et al. Tuning the catalytic activity of Ag(110)-supported Fe phthalocyanine in the oxygen reduction reaction. Nature Materials[J], 2012, 11(11): 970-977.

29.          Subbaraman, R, Danilovic, N, Lopes, P P et al. Origin of Anomalous Activities for Electrocatalysts in Alkaline Electrolytes. Journal of Physical Chemistry C[J], 2012, 116(42): 22231-22237.

30.          Li, D G, Wang, C, Strmcnik, D S et al. Functional links between Pt single crystal morphology and nanoparticles with different size and shape: the oxygen reduction reaction case. Energy & Environmental Science[J], 2014, 7(12): 4061-4069.

31.          Wan, L J, Moriyama, T, Ito, M et al. In situ STM imaging of surface dissolution and rearrangement of a Pt-Fe alloy electrocatalyst in electrolyte solution. Chemical Communications[J], 2002(1): 58-59.

32.          Todoroki, N, Iijima, Y, Takahashi, R et al. Structure and Electrochemical Stability of Pt-Enriched Ni/Pt(111) Topmost Surface Prepared by Molecular Beam Epitaxy. Journal of the Electrochemical Society[J], 2013, 160(6): F591-F596.

33.          Yoshimoto, S, Tada, A & Itaya, K In situ scanning tunneling microscopy study of the effect of iron octaethylporphyrin adlayer on the electrocatalytic reduction of O-2 on Au(111). Journal of Physical Chemistry B[J], 2004, 108(17): 5171-5174.

34.          Grumelli, D, Wurster, B, Stepanow, S et al. Bio-inspired nanocatalysts for the oxygen reduction reaction. Nature Communications[J], 2013, 4: 6.

35.          Climent, V, Fu, Y C, Chumillas, S et al. Probing the Electrocatalytic Oxygen Reduction Reaction Reactivity of Immobilized Multicopper Oxidase CueO. Journal of Physical Chemistry C[J], 2014, 118(29): 15754-15765.

36.          Sun, S R, Jiang, N & Xia, D G Density Functional Theory Study of the Oxygen Reduction Reaction on Metalloporphyrins and Metallophthalocyanines. Journal of Physical Chemistry C[J], 2011, 115(19): 9511-9517.

37.          Sun, Y, Chen, K X, Jia, L et al. Toward understanding macrocycle specificity of iron on the dioxygen-binding ability: a theoretical study. Physical Chemistry Chemical Physics[J], 2011, 13(30): 13800-13808.

38.          Hulsken, B, Van Hameren, R, Gerritsen, J W et al. Real-time single-molecule imaging of oxidation catalysis at a liquid-solid interface. Nature Nanotechnology[J], 2007, 2(5): 285-289.

39.          den Boer, D, Li, M, Habets, T et al. Detection of different oxidation states of individual manganese porphyrins during their reaction with oxygen at a solid/liquid interface. Nature Chemistry[J], 2013, 5(7): 621-627.

40.          Li, M, den Boer, D, Iavicoli, P et al. Tip-induced chemical manipulation of metal porphyrins at a liquid/solid interface. Journal of the American Chemical Society[J], 2014, 136(50): 17418-17421.

41.          Nie, Y, Li, L & Wei, Z D Recent advancements in Pt and Pt-free catalysts for oxygen reduction reaction. Chemical Society Reviews[J], 2015, 44(8): 2168-2201.

42.          Ramaswamy, N, Tylus, U, Jia, Q Y et al. Activity Descriptor Identification for Oxygen Reduction on Nonprecious Electrocatalysts: Linking Surface Science to Coordination Chemistry. Journal of the American Chemical Society[J], 2013, 135(41): 15443-15449.

43.          Jia, Q, Ramaswamy, N, Hafiz, H et al. Experimental Observation of Redox-Induced Fe-N Switching Behavior as a Determinant Role for Oxygen Reduction Activity. Acs Nano[J], 2015, 9(12): 12496-12505.

44.          Strbac, S, Srejic, I, Smiljanic, M et al. The effect of rhodium nanoislands on the electrocatalytic activity of gold for oxygen reduction in perchloric acid solution. Journal of Electroanalytical Chemistry[J], 2013, 704: 24-31.

45.  Sheng, Z H, Gao, H L, Bao, W J et al. Synthesis of boron doped graphene for oxygen reduction reaction in fuel cells. Journal of Materials Chemistry[J], 2012, 22(2): 390-395.

Options
文章导航

/

版权所有 © 《电化学(中英文)》编辑部
地址:福建省厦门市思明区厦门大学D信箱 邮编:361005
电话:0592-2181469  Email:dianhx@xmu.edu.cn
技术支持:北京玛格泰克科技发展有限公司