Different polyaniline/carbon nanotube composites as Pt catalyst supports for methanol electro-oxidation
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- 作者:Xingwei Li ; Jiadi Wei ; Yuzheng Chai ; Shuo Zhang ; Min Zhou
- 刊名:Journal of Materials Science
- 出版年:2015
- 出版时间:February 2015
- 年:2015
- 卷:50
- 期:3
- 页码:1159-1168
- 全文大小:1,765 KB
- 参考文献:1. Sharma S, Pollet BG (2012) Support materials for PEMFC and DMFC electrocatalysts: a review. J Power Sources 208:96-19 CrossRef
2. Veziroglu A, Macario R (2011) Fuel cell vehicles: state of the art with economic and environmental concerns. Int J Hydrog Energy 36:25-3 CrossRef
3. Wang K, Hissel D, Péra MC, Steiner N, Marra D, Sorrentino M, Pianese C, Monteverde M, Cardone P, Saarinen J (2011) A review on solid oxide fuel cell models. Int J Hydrog Energy 36:7212-228 CrossRef
4. Gao H, He JB, Wang Y, Deng N (2012) Advantageous combination of solid carbon paste and a conducting polymer film as a support of platinum electrocatalyst for methanol fuel cell. J Power Sources 205:164-72 CrossRef
5. Zhao HB, Li L, Yang J, Zhang YM (2008) Nanostructured polypyrrole/carbon composite as Pt catalyst support for fuel cell applications. J Power Sources 184:375-80 CrossRef
6. He DP, Zeng C, Xu C, Cheng NC, Li HG, Mu SC, Pan M (2011) Polyaniline-functionalized carbon nanotube supported platinum catalysts. Langmuir 27:5582-588 CrossRef
7. Zhao X, Yin M, Ma L, Liang L, Liu CP, Liao JH, Lu TH, Xing W (2011) Recent advances in catalysts for direct methanol fuel cells. Energy Environ Sci 4:2736-753 CrossRef
8. Antolini E (2010) Composite materials: an emerging class of fuel cell catalyst supports. Appl Catal B 100:413-26 CrossRef
9. Lota G, Fic K, Frackowiak EE (2011) Carbon nanotubes and their composites in electrochemical applications. Energy Environ Sci 4:1592-605 CrossRef
10. Tang SH, Sun GQ, Qi J, Sun SG, Guo JS, Xin Q, Haarberg GM (2010) Review of new carbon materials as catalyst supports in direct alcohol fuel cells. Chin J Catal 31:12-7 CrossRef
11. Basri S, Kamarudin SK, Daud WRW, Yaakub Z (2010) Nanocatalyst for direct methanol fuel cell (DMFC). Int J Hydrog Energy 35:7957-970 CrossRef
12. Huang JE, Guo DJ, Yao YG, Li HL (2005) High dispersion and electrocatalytic properties of platinum nanoparticles on surface-oxidized single-walled carbon nanotubes. J Electroanal Chem 577:93-7 CrossRef
13. Liu Z, Lin X, Lee JY, Zhang W, Han M, Gan LM (2002) Preparation and characterization of platinum-based electrocatalysts on multiwalled carbon nanotubes for proton exchange membrane fuel cells. Langmuir 18:4054-060 CrossRef
14. MacDiarmid AG (2001) “Synthetic metals- a novel role for organic polymers (nobel lecture). Angew Chem Int Ed 40:2581-590 CrossRef
15. Wan MX (2009) Some issues related to polyaniline micro-/nanostructures. Macromol Rapid Commun 30:963-75 CrossRef
16. Antolini E, Gonzalez ER (2009) Polymer supports for low-temperature fuel cell catalysts. Appl Catal A 365:1-9 CrossRef
17. Shao YY, Sui JH, Yin GP, Gao YZ (2008) Nitrogen-doped carbon nanostructures and their composites as catalytic materials for proton exchange membrane fuel cell. Appl Catal B 79:89-9
文摘
Polyaniline/carbon nanotube composites as Pt catalyst supports for methanol electro-oxidation have been reported. Conventionally, the size and distribution of Pt catalysts were improved in the presence of polyaniline (PAni), and an interaction between Pt and N atoms in PAni could prevent Pt catalysts from aggregation and detachment. In this work, polyaniline-modified multi-walled carbon nanotube (PAni-MWCNT) composites, with different loading levels of PAni, were synthesized by in situ oxidative polymerization of aniline on the surface of MWCNT. And Pt catalysts supported by these composites were prepared by the liquid phase reduction. Our studies revealed that the loading level of PAni affected the proportion of the different valence Pt components. And the proportion of Pt(0) and Pt(II) was also important for improving the electro-catalytic performance of Pt catalysts. The proper proportion of Pt(II) was essential for coordination of Pt with oxygen-containing ligands (OH·, H2O) and thus accelerating oxidation of Pt (CO)ads with release of CO2 by improving the tolerance to intermediate carbonaceous species.