Palladium networks decorated by cuprous oxide for remarkably enhanced electrocatalytic activity of methanol oxidation reaction with high CO-tolerance

Journal of Power Sources

Volumn 329, Issue , 2016, Pages 115-122

  Ji, Yuanyuan ^a   Ying, Ye ^a   Pan, Yuxia ^a   Li, Mengzhu ^a   Guo, Xiaoyu ^a   Wu, Yiping ^a   Wen, Ying ^a   Yang, Haifeng ^a  

^a SHANGHAI NORMAL UNIVERSITY   (China)

Author keywords

CO tolerance; Cu2O; Inositol hexakisphosphate; Methanol oxidation; Palladium

Indexed keywords

ALCOHOLS; CATALYSTS; COPPER OXIDES; DIRECT METHANOL FUEL CELLS (DMFC); FUEL CELLS; HIGH RESOLUTION TRANSMISSION ELECTRON MICROSCOPY; METHANOL; METHANOL FUELS; NANORODS; OXIDATION; PALLADIUM; POLYOLS; SUGARS; TRANSMISSION ELECTRON MICROSCOPY;

CO TOLERANCE; ELECTROCATALYTIC ACTIVITY; INOSITOL HEXAKISPHOSPHATE; METHANOL OXIDATION; METHANOL OXIDATION REACTIONS; PD/C CATALYST; REACTION BEDS; TRANSMISSION ELECTRON MICROSCOPY IMAGES;

CATALYST ACTIVITY;

EID: 84983429899     PISSN: 03787753     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jpowsour.2016.08.076     Document Type: Article

References (52)

1. [1] Guo, S., Zhang, S., Sun, X., Sun, S., Synthesis of ultrathin FePtPd nanowires and their use as catalysts for methanol oxidation reaction. J. Am. Chem. Soc. 133 (2011), 15354–15357.
2. [2] Li, M.Z., Pan, Y.X., Guo, X.Y., Liang, Y.H., Wu, Y.P., Wen, Y., Yang, H.F., Pt/single-stranded DNA/graphene nanocomposite with improved catalytic activity and CO tolerance. J. Mater. Chem. A 3 (2015), 10353–10359.
3. [3] Wang, H., Ishihara, S., Ariga, K., Yamauchi, Y., All-metal layer-by-layer films: bimetallic alternate layers with accessible mesopores for enhanced electrocatalysis. J. Am. Chem. Soc. 134 (2012), 10819–10821.
4. [4] Wang, A.L., Xu, H., Feng, J.X., Ding, L.X., Tong, Y.X., Li, G.R., Design of Pd/PANI/Pd sandwich-structured nanotube array catalysts with special shape effects and synergistic effects for ethanol electrooxidation. J. Am. Chem. Soc. 135 (2013), 10703–10709.
5. 3 nanocages with enhanced electrocatalytic activity for the methanol oxidation reaction. J. Am. Chem. Soc. 134 (2012), 13934–13937.
6. [6] Zhao, X., Chen, S., Fang, Z.C., Ding, J., Sang, W., Wang, Y.C., Zhao, J., Peng, Z.M., Zeng, J., Octahedral Pd@Pt1.8Ni core−shell nanocrystals with ultrathin PtNi alloy shells as active catalysts for oxygen reduction reaction. J. Am. Chem. Soc. 137 (2015), 2804–2807.
7. [7] Chen, L., Guo, H., Fujita, T., Hirata, A., Zhang, W., Inoue, A., Chen, M., Nanoporous PdNi bimetallic catalyst with enhanced electrocatalytic performances for electro-oxidation and oxygen reduction reactions. Adv. Funct. Mater. 21 (2011), 4364–4370.
8. [8] Yin, Z., Zheng, H.J., Ma, D., Bao, X.H., Porous palladium nanoflowers that have enhanced methanol electro-oxidation activity. J. Phys. Chem. C 113 (2009), 1001–1005.
9. [9] Mahapatra, S.S., Shekhar, S., Thakur, B.K., Priyadarshi, H., Synthesis and characterization of electrodeposited C-PANI-Pd-Ni composite electrocatalyst for methanol oxidation. Int. J. Electrochem. 2014 (2014), 383892–383899.
10. [10] Xiao, L., Zhuang, L., Liu, Y., Lu, J., Abrúna, H.D., Activating Pd by morphology tailoring for oxygen reduction. J. Am. Chem. Soc. 131 (2009), 602–608.
11. [11] Lim, B., Jiang, M., Camargo, P., Cho, E., Tao, J., Lu, X., Zhu, Y., Xia, Y., Pd-Pt bimetallic nanodendrites with high activity for oxygen reduction. Science 324 (2009), 1302–1305.
12. [12] Tominaka, S., Shigeto, M., Nishizeko, H., Osaka, T., Synthesis of mesoporous PtCu film modified with Ru submonolayer as catalyst for methanol electrooxidation. Chem. Commun. 46 (2010), 8989–8991.
13. [13] Zhu, C.Z., Wen, D., Oschatz, M., Holzschuh, M., Liu, W., Herrmann, A.K., Simon, F., Kaskel, S., Eychmüller, A., Kinetically controlled synthesis of PdNi bimetallic porous nanostructures with enhanced electrocatalytic activity. Small 11 (2015), 1430–1434.
14. [14] Yu, F.J., Zhou, W.Z., Bellabarba, R.M., Tooze, R.P., One-step synthesis and shape-control of CuPd nanowire networks. Nanoscale 6 (2014), 1093–1098.
15. [15] Liu, M.M., Lu, Y.Z., Chen, W., PdAg nanorings supported on graphene nanosheets: highly methanol-tolerant cathode electrocatalyst for alkaline fuel cells. Adv. Funct. Mater. 23 (2013), 1289–1296.
16. 2 nanotubes for ethanol electrooxidation: synthesis and electrochemical properties. ACS Appl. Mater. Interfaces 7 (2015), 24533–24542.
17. 4)-promoted Pd/C electrocatalysts for alcohol electrooxidation in alkaline media. Electrochim. Acta 53 (2008), 2610–2618.
18. [18] Zhang, M.M., Yan, Z.X., Xie, J.M., Core/shell Ni@Pd nanoparticles supported on MWCNTs at improved electrocatalytic performance for alcohol oxidation in alkaline media. Electrochim. Acta 77 (2012), 237–243.
19. [19] Liu, M.M., Zhang, R.Z., Chen, W., Graphene-supported nanoelectrocatalysts for fuel cells: synthesis, properties, and applications. Chem. Rev. 114 (2014), 5117–5160.
20. [20] Qu, W.L., Gu, D.M., Wang, Z.B., Zhang, J.J., High stability and high activity Pd/ITO-CNTs electrocatalyst for direct formic acid fuel cell. Electrochim. Acta 137 (2014), 676–684.
21. 2O/GNs composites and their electro-photosynergistic catalytic properties for methanol oxidation. J. Mater. Chem. A 2 (2014), 21010–21019.
22. [22] Chen, A.C., Ostrom, C., Palladium-based nanomaterials: synthesis and electrochemical applications. Chem. Rev. 115 (2015), 11999–12044.
23. 2O homojunction solar cells. J. Phys. Chem. Lett. 1 (2010), 2666–2670.
24. 2O octahedrons on h-BN nanosheets for p-nitrophenol reduction. ACS Appl. Mater. Interfaces 6 (2014), 14469–14476.
25. [25] Kevin, M., Ong, W., Lee, G., Ho, G., Formation of hybrid structures: copper oxide nanocrystals templated on ultralong copper nanowires for open network sensing at room temperature. Nanotechnology 22 (2011), 235701–235710.
26. 2O nanocrystals for oxygen reduction reaction. J. Phys. Chem. C 117 (2013), 13872–13878.
27. [27] Wang, N., Wen, Y., Wang, Y., Zhang, R., Zhang, X.Y., Xiong, D.H., Yang, H.F., Facile and controlled synthesis of self-conjugated Ag@IP6-micelle compositions for surface-enhanced spectroscopic application. J. Mater. Chem. 20 (2010), 2317–2321.
28. [28] Yang, T.X., Guo, X.Y., Wang, H., Fu, S.Y., Yu, J., Wen, Y., Yang, H.F., Au dotted magnetic network nanostructure and its application for on-site monitoring femtomolar level pesticide. Small 10 (2014), 1325–1331.
29. [29] Xu, W.C., Zhu, S.L., Li, Z.Y., Cui, Z.D., Yang, X.J., Evolution of palladium/copper oxide-titanium dioxide nanostructures by dealloying and their catalytic performance for methanol electro-oxidation. J. Power Sources 274 (2015), 1034–1042.
30. [30] Qu, W.L., Gu, D.M., Wang, Z.B., Zhang, J.J., High stability and high activity Pd/ITO-CNTs electrocatalyst for directformic acid fuel cell. Electrochim. Acta 137 (2014), 676–684.
31. [31] Zhang, J.F., Xu, Y., Zhang, B., Facile synthesis of 3D Pd-P nanoparticle networks with enhanced electrocatalytic performance towards formic acid electrooxidation. Chem. Commun. 50 (2014), 13451–13453.
32. [32] Huang, J.F., Vongehr, S., Tang, S.C., Lu, H.M., Meng, X.K., Highly catalytic Pd-Ag bimetallic dendrites. J. Phys. Chem. C 114 (2010), 15005–15010.
33. 2O/Cu composite and its excellent microwave absorption properties. Mater. Lett. 109 (2013), 112–115.
34. [34] Xu, W.C., Zhu, S.L., Li, Z.Y., Cui, Z.D., Yang, X.J., Preparation of nanoporous Pd/CuO by dealloying and their electrocatalysis for methanol in alkaline condition. J. Electrochem. Soc. 161 (2014), 1474–1480.
35. [35] Cai, J.D., Zeng, Y.Z., Guo, Y.L., Copper@palladium-copper core-shell nanospheres as a highly effective electrocatalyst for ethanol electro-oxidation in alkaline media. J. Power Sources 270 (2014), 257–261.
36. [36] Zhang, B., Yuan, Y., Philippot, K., Yan, N., Ag-Pd and CuO-Pd nanoparticles in a hydroxyl-group functionalized ionic liquid: synthesis characterization and catalytic performance. Catal. Sci. Technol. 5 (2015), 1683–1692.
37. 2O nanoparticles. Adv. Mater. 22 (2010), 1910–1914.
38. [38] Liu, X.Y., Xu, G.R., Chen, Y., Lu, T.H., Tang, Y.W., Xing, W., A strategy for fabricating porous PdNi@Pt core-shell nanostructures and their enhanced activity and durability for the methanol electrooxidation. Sci. Rep. 5 (2015), 7619–7624.
39. [39] Wu, Y.E., Wang, D.S., Zhou, G., Yu, R., Chen, C., Li, Y.D., Sophisticated construction of Au islands on Pt−Ni: an ideal trimetallic nanoframe catalyst. J. Am. Chem. Soc. 136 (2014), 11594–11597.
40. [40] Niu, X.H., Zhao, H.L., Lan, M.B., Palladium deposits spontaneously grown on nickel foam for electro-catalyzing methanol oxidation: effect of precursors. J. Power Sources 306 (2016), 361–368.
41. [41] Qiu, X.Y., Dai, Y.X., Zhu, X.S., Zhang, H.Y., Wu, P., Tang, Y.W., Wei, S.H., Template-engaged synthesis of hollow porous platinum-palladium alloy nanospheres for efficient methanol electro-oxidation. J. Power Sources 302 (2016), 195–201.
42. [42] Li, Z.S., Ye, L.T., Lei, F.L., Wang, Y.L., Xu, S.H., Lin, S., Enhanced electro-photo synergistic catalysis of Pt (Pd)/ZnO/graphene composite for methanol oxidation under visible light irradiation. Electrochim. Acta 188 (2016), 450–460.
43. [43] Zhao, J., Liu, Z.S., Li, H.Q., Hu, W.B., Zhao, C.Z., Zhao, P., Shi, D.L., Development of a highly active electrocatalyst via ultrafine Pd nanoparticles dispersed on pristine graphene. Langmuir 31 (2015), 2576–2583.
44. [44] Jurzinsky, T., Kammerer, P., Cremers, C., Pinkwart, K., Tübke, J., Investigation of ruthenium promoted palladium catalysts for methanol electrooxidation in alkaline media. J. Power Sources 303 (2016), 182–193.
45. [45] Qian, H.Y., Chen, S.W., Fu, Y.S., Wang, X., Platinum-palladium bimetallic nanoparticles on graphitic carbon nitride modified carbon black: a highly electroactive and durable catalyst for electrooxidation of alcohols. J. Power Sources 300 (2015), 41–48.
46. [46] Li, Y., Fu, Z.Y., Su, B.L., Hierarchically structured porous materials for energy conversion and storage. Adv. Funct. Mater. 22 (2012), 4634–4667.
47. [47] Hofstead-Duffy, A.M., Chen, D.J., Sun, S.G., Tong, Y.J., Origin of the current peak of negative scan in the cyclic voltammetry of methanol electro-oxidation on Pt-based electrocatalysts: a revisit to the current ratio criterion. J. Mater. Chem. 22 (2012), 5205–5208.
48. [48] Melvin, A.A., Joshi, V.S., Poudyal, D.C., Khushalani, D., Haram, S.K., Electrocatalyst on insulating support?: hollow silica spheres loaded with Pt nanoparticles for methanol oxidation. ACS Appl. Mater. Interfaces 7 (2015), 6590–6595.
49. [49] Chen, Z.W., Waje, M., Li, W.Z., Yan, Y.S., Supportless Pt and PtPd nanotubes as electrocatalysts for oxygen-reduction reactions. Angew. Chem. Int. Ed. 46 (2007), 4060–4063.
50. [50] Kabbabi, A., Faure, R., Durand, R., Beden, B., Hahn, F., Leger, J.M., Lamy, C., In situ FTIRS study of the electrocatalytic oxidation of carbon monoxide and methanol at platinum-ruthenium bulk alloy electrodes. J. Electroanal. Chem. 444 (1998), 41–53.
51. [51] Yang, G.X., Chen, Y., Zhou, Y.M., Tang, Y.W., Lu, T.H., Preparation of carbon supported Pd-P catalyst with high content of element phosphorus and its electrocatalytic performance for formic acid oxidation. Electrochem. Commun. 12 (2010), 492–495.
52. [52] Miao, T.T., Song, Y.H., Bi, C.X., Xia, H.B., Wang, D.Y., Tao, X.T., Correlation of surface Ag content in AgPd shells of ultrasmall core-shell Au@AgPd nanoparticles with enhanced electrocatalytic performance for ethanol oxidation. J. Phys. Chem. C 119 (2015), 18434–18443.