Anodic oxidation of formic acid on PdAuIr/C-Sb2O5·SnO2 electrocatalysts prepared by borohydride reduction

A. O. Neto; J. Nandenha; R. F. B. De Souza; G. S Buzzo; J. C. M. Silva; E. V. Spinacé; M. H. M. T. Assumpção

Anodic oxidation of formic acid on PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts prepared by borohydride reduction

Instituto de Pesquisas Energéticas e Nucleares-IPEN-CNEN/SP, Cidade Universitária, São Paulo 05508-900, Brazil

详细信息

中图分类号: TM911.4
计量
- 文章访问数: 600
- HTML全文浏览量: 13
- PDF下载量: 630
- 被引次数: 0
出版历程
- 收稿日期: 2013-12-06
- 修回日期: 2014-04-17
- 刊出日期: 2014-07-30

Anodic oxidation of formic acid on PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts prepared by borohydride reduction

Instituto de Pesquisas Energéticas e Nucleares-IPEN-CNEN/SP, Cidade Universitária, São Paulo 05508-900, Brazil

摘要

摘要: PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts with Pd：Au：Ir molar ratios of 90：5：5， 70：20：10 and 50：45：5 were prepared by borohydride reduction method. These electrocatalysts were characterized by EDX， X-ray diffraction， transmission electron microscopy and the catalytic activity toward formic acid electro-oxidation in acid medium investigated by cyclic voltammetry （CV）， chroamperometry （CA） and tests on direct formic acid fuel cell （DFAFC） at 100℃. X-ray diffractograms of PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts showed the presence of Pd fcc phase， Pd-Au fcc alloys， carbon and ATO phases， while Ir phases were not observed. TEM micrographs and histograms indicated that the nanoparticles were not well dispersed on the support and some agglomerates. The cyclic voltammetry and chroamperometry studies showed that PdAuIr/C-Sb₂O₅·SnO₂ （50：45：5） had superior performance toward formic acid electro-oxidation at 25℃ compared to PdAuIr/C-Sb₂O₅·SnO₂ （70：20：10）， PdAuIr/C-Sb₂O₅·SnO₂ （90：5：5） and Pd/C-Sb₂O₅·SnO₂ electrocatalysts. The experiments in a single DFAFC also showed that all PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts exhibited higher performance for formic acid oxidation in comparison with Pd/C-Sb₂O₅·SnO₂ electrocatalysts， however PdAuIr/C-Sb₂O₅·SnO₂ （90：5：5） had superior performance. These results indicated that the addition of Au and Ir to Pd favor the electro-oxidation of formic acid， which could be attributed to the bifunctional mechanism （the presence of ATO， Au and Ir oxides species） associated to the electronic effect （Pd-Au fcc alloys）.
- PdAuIr/C-Sb₂O₅· /
- SnO₂electrocatalysts /
- formicacidoxidation /
- fuelcell /
- borohydridereductionprocess
Abstract: PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts with Pd:Au:Ir molar ratios of 90:5:5, 70:20:10 and 50:45:5 were prepared by borohydride reduction method. These electrocatalysts were characterized by EDX, X-ray diffraction, transmission electron microscopy and the catalytic activity toward formic acid electro-oxidation in acid medium investigated by cyclic voltammetry (CV), chroamperometry (CA) and tests on direct formic acid fuel cell (DFAFC) at 100℃. X-ray diffractograms of PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts showed the presence of Pd fcc phase, Pd-Au fcc alloys, carbon and ATO phases, while Ir phases were not observed. TEM micrographs and histograms indicated that the nanoparticles were not well dispersed on the support and some agglomerates. The cyclic voltammetry and chroamperometry studies showed that PdAuIr/C-Sb₂O₅·SnO₂ (50:45:5) had superior performance toward formic acid electro-oxidation at 25℃ compared to PdAuIr/C-Sb₂O₅·SnO₂ (70:20:10), PdAuIr/C-Sb₂O₅·SnO₂ (90:5:5) and Pd/C-Sb₂O₅·SnO₂ electrocatalysts. The experiments in a single DFAFC also showed that all PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts exhibited higher performance for formic acid oxidation in comparison with Pd/C-Sb₂O₅·SnO₂ electrocatalysts, however PdAuIr/C-Sb₂O₅·SnO₂ (90:5:5) had superior performance. These results indicated that the addition of Au and Ir to Pd favor the electro-oxidation of formic acid, which could be attributed to the bifunctional mechanism (the presence of ATO, Au and Ir oxides species) associated to the electronic effect (Pd-Au fcc alloys).
- PdAuIr/C-Sb₂O₅· /
- SnO₂ electrocatalysts /
- formic acid oxidation /
- fuel cell /
- borohydride reduction process

HTML全文

参考文献(24)

MARINSEK M, SALA M, JANCAR B. A study towards superior carbon nanotubes-supported Pd-based catalysts for formic acid electro-oxidation: Preparation, properties and characterization[J]. J Power Sources, 2013, 235: 111-116.

NANDENHA J, DE SOUZA R F B, ASSUMPÇÃO M H M T, SPINACÉ E V, NETO A O. Preparation of PdAu/C-Sb₂O₅·SnO₂ electrocatalysts by borohydride reduction process for direct formic acid fuel cell Ionics[J]. Inoics, 2013, 19(9): 1207-1213.

FENG L, YAO S, ZHAO X, YAN L, LIU C, XING W. Electrocatalytic properties of Pd/C catalyst for formic acid electrooxidation promoted by europium oxide[J]. J Power Sources, 2012, 197: 38-43.

NANDENHA J, DE SOUZA R F B, ASSUMPÇÃO M H M T, SPINACÉ E V, NETO A O. Electro-oxidation of formic acid on PdIr/C-Sb₂O₅·SnO₂ electrocatalysts prepared by borohydride reduction[J]. Int J Electrochem Sci, 2013, 8: 9171-9179.

LU L, SHEN L, SHA Y, CHEN T, JIANG G, GE C, TANG Y, CHEN Y, LU T. New insights into enhanced electrocatalytic performance of carbon supported Pd-Cu catalyst for formic acid oxidation[J]. Electrochim Acta, 2012, 85: 187-194.

WANG X, TANG Y W, GAO Y, LU T H. Carbon-supported Pd-Ir catalyst as anodic catalyst in direct formic acid fuel cell[J]. J Power Sources, 2008, 175(2): 784-788.

ALDEN L R, HAN D K, MATSUMOTO F, ABRUN A D, DISALVO F J. Intermetallic PtPb nanoparticles prepared by sodium naphthalide reduction of metal-organic precursors: Electrocatalytic oxidation of formic acid[J]. Chem Mater, 2006, 18(23): 5591-5596.

ZHOU W J, LEE J Y. Highly active core-shell Au@Pd catalyst for formic acid electrooxidation[J]. Electrochem Commun, 2007, 9(7): 1725-1729.

WANG R F, LIAO S J, JI S. High performance Pd-based catalysts for oxidation of formic acid[J]. J Power Sources, 2008, 180(1): 205-208.

YANG G, CHEN Y, ZHOU Y, TANG Y, LU T. Preparation of carbon supported Pd-P catalyst with high content of element phosphorus and its electrocatalytic performance for formic acid oxidation[J]. Electrochem Commun, 2010, 12(3): 492-495.

WANG R, WANG H, FENG H, JI S. Palladium decorated nickel nanoparticles supported on carbon for formic acid oxidation[J]. Int J Electrochem Sci, 2013, 8: 6068-6076.

CHIOU Y J, CHEN K Y, LIN H M, LIOU W J, LIOU H W, WU S H, MIKOLAJCZUK A, MAZURKIEWICZ M, MALOLEPSZY A, STOBINSKI L, BORODZINSKI A, KEDZIERZAWSKI P, KURZYDLOWSKI K, CHIEN S H, CHEN W C. Electrocatalytic properties of hybrid palladium gold/multi-walled carbon nanotube materials in fuel cell applications[J]. Phys Status Solidi A, 2011, 208(8): 1778-1782.

PAN C, LI Y, MA Y, ZHAO X, ZHANG Q. Platinum-antimony doped tin oxide nanoparticles supported on carbon black as anode catalysts for direct methanol fuel cells[J]. Power Sources, 2011, 196(15): 6228-6231.

WU X, SCOTT K. RuO₂ supported on Sb-doped SnO₂ nanoparticles for polymer electrolyte membrane water electrolysers[J]. Int J Hydrogen Energy, 2011, 36(10): 5806-5810.

LIU H, SONG C, ZHANG L, ZHANG J, WANG H, WILKINSON D P. A review of anode catalysis in the direct methanol fuel cel[J]. J Power Sources, 2006, 155(2): 95-110.

LUX K W, CAIRNS E J. Lanthanide-platinum intermetallic compounds as anode electrocatalysts for direct ethanol PEM fuel cells: I. Synthesis and characterization of Ln Pt 2 ( Ln=Ce, Pr) nanopowders[J]. J Electrochem Soc, 2006, 153(6): A1132-A1138.

DELIME F, LEGER J M, LAMY C. Optimization of platinum dispersion in Pt-PEM electrodes: Application to the electrooxidation of ethanol[J]. J Appl Electrochem, 1998, 28: 27-35.

NETO A O, BRANDALISE M, DIAS R R, AYOUB J M S, SILVA A C, PENTEADO J C, LINARDI M, SPINACE EV. The performance of Pt nanoparticles supported on Sb₂O₅·SnO₂, on carbon and on physical mixtures of Sb₂O₅·SnO₂ and carbon for ethanol electro-oxidation[J]. Int J Hydrogen Energy, 2010, 35(17): 9177-9181.

AYOUB J M S, DE SOUZA R F B, SILVA J C M, PIASENTIN R M, SPINACÉ E V, SANTOS MC, NETO A O. Ethanol electro-oxidation on PtSn/C-ATO electrocatalysts[J]. Int J Electrochem Sci, 2012, 7: 11351-11362.

PIASENTIN R M, SPINACE E V, TUSI M M, NETO A O. Preparation of PdPtSn/C-Sb₂O₅.SnO₂ electrocatalysts by borohydride reduction for ethanol electro-oxidation in alkaline medium[J]. Int J Electrochem Sci, 2011, 6: 2255-2263.

BRANDALISE M, TUSI M M, PIASENTIN R M, DOS SANTOS M C, SPINAC E V, NETO A O. Synthesis of PdAu/C and PdAuBi/C Electrocatalysts by borohydride reduction method for ethylene glycol electro-oxidation in alkaline medium[J]. Int J Electrochem Sci, 2012, 7: 9609-9621.

ZHU L D, ZHAO T S, XU J B, LIANG Z X. Preparation and characterization of carbon-supported sub-monolayer palladium decorated gold nanoparticles for the electro-oxidation of ethanol in alkaline media[J]. J Power Sources, 2009, 187(1): 80-84.

RIBEIRO J, DOS ANJOS D M, KOKOH K B, COUTANCEAU C, LÉGER J M, OLIVI P, DE ANDRADE A R, TREMILIOSI-FILHO G. Carbon-supported ternary PtSnIr catalysts for direct ethanol fuel cell[J]. Electrochimica Acta, 2007, 52(24): 6997-7006.

GERMAIN P S, PELL W G, CONWAY B E. Evaluation and origins of the difference between double-layer capacitance behaviour at Au-metal and oxidized Au surfaces[J]. Electrochim Acta, 2004, 49(11): 1775-1788.

施引文献

资源附件(0)

访问统计

点击查看大图

计量

文章访问数: 600
HTML全文浏览量: 13
PDF下载量: 630
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

留言板

Anodic oxidation of formic acid on PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts prepared by borohydride reduction

计量

Anodic oxidation of formic acid on PdAuIr/C-Sb₂O₅·SnO₂ electrocatalysts prepared by borohydride reduction

计量

目录

2023年《燃料化学学报（中英文）》评优结果公布！

留言板