表面技术
錶麵技術
표면기술
SURFACE TECHNOLOGY
2015年
6期
44-48
,共5页
刘双任%陈金伟%朱雪婧%张洁%江义武%王瑞林
劉雙任%陳金偉%硃雪婧%張潔%江義武%王瑞林
류쌍임%진금위%주설청%장길%강의무%왕서림
燃料电池%甲酸%铂%铅%电氧化
燃料電池%甲痠%鉑%鉛%電氧化
연료전지%갑산%박%연%전양화
fuel cell%formic acid%platinum%lead%electro-oxidation
目的:通过Pb元素的添加来提高Pt/C催化剂电催化氧化甲酸的性能。方法通过乙二醇协助硼氢化钠还原法,以氯铂酸为Pt源和硝酸铅为Pb源制备不同原子比的Pt x Pb/C催化剂。采用X射线衍射光谱法( XRD)和透射电子显微镜技术( TEM)表征样品的晶体结构和颗粒形貌;采用循环伏安法表征样品催化氧化甲酸的性能。结果利用乙二醇协助硼氢化钠还原法成功制得了Pt和Pb原子比不同的Ptx Pb/C催化剂,XRD和TEM测试结果表明这些样品均为Pt的面心立方结构,且颗粒大小均一、分散均匀,其平均粒径为4 nm左右。循环伏安测试结果表明Ptx Pb/C催化剂催化氧化甲酸的性能优于商业Pt/C催化剂的催化性能,且受Pt和Pb原子比的影响,当原子比为5:1时,其对氧化甲酸的催化性能最好,峰电位对应的Pt的比质量活性达到2000 mA/( mg Pt),远远高于商业Pt/C,同时计时电流曲线表明其具备良好的稳定性。结论 Pb原子的加入影响了Pt原子的电子结构,与Pb对Pt的协同作用共同促进了CO等中间产物在Pt表面的快速氧化,降低了催化氧化甲酸的初始电位,促使甲酸在低电位直接氧化为CO2和H2 O,提高了其催化氧化甲酸的峰电流,有效减轻了Pt中毒,提高了其催化活性。
目的:通過Pb元素的添加來提高Pt/C催化劑電催化氧化甲痠的性能。方法通過乙二醇協助硼氫化鈉還原法,以氯鉑痠為Pt源和硝痠鉛為Pb源製備不同原子比的Pt x Pb/C催化劑。採用X射線衍射光譜法( XRD)和透射電子顯微鏡技術( TEM)錶徵樣品的晶體結構和顆粒形貌;採用循環伏安法錶徵樣品催化氧化甲痠的性能。結果利用乙二醇協助硼氫化鈉還原法成功製得瞭Pt和Pb原子比不同的Ptx Pb/C催化劑,XRD和TEM測試結果錶明這些樣品均為Pt的麵心立方結構,且顆粒大小均一、分散均勻,其平均粒徑為4 nm左右。循環伏安測試結果錶明Ptx Pb/C催化劑催化氧化甲痠的性能優于商業Pt/C催化劑的催化性能,且受Pt和Pb原子比的影響,噹原子比為5:1時,其對氧化甲痠的催化性能最好,峰電位對應的Pt的比質量活性達到2000 mA/( mg Pt),遠遠高于商業Pt/C,同時計時電流麯線錶明其具備良好的穩定性。結論 Pb原子的加入影響瞭Pt原子的電子結構,與Pb對Pt的協同作用共同促進瞭CO等中間產物在Pt錶麵的快速氧化,降低瞭催化氧化甲痠的初始電位,促使甲痠在低電位直接氧化為CO2和H2 O,提高瞭其催化氧化甲痠的峰電流,有效減輕瞭Pt中毒,提高瞭其催化活性。
목적:통과Pb원소적첨가래제고Pt/C최화제전최화양화갑산적성능。방법통과을이순협조붕경화납환원법,이록박산위Pt원화초산연위Pb원제비불동원자비적Pt x Pb/C최화제。채용X사선연사광보법( XRD)화투사전자현미경기술( TEM)표정양품적정체결구화과립형모;채용순배복안법표정양품최화양화갑산적성능。결과이용을이순협조붕경화납환원법성공제득료Pt화Pb원자비불동적Ptx Pb/C최화제,XRD화TEM측시결과표명저사양품균위Pt적면심립방결구,차과립대소균일、분산균균,기평균립경위4 nm좌우。순배복안측시결과표명Ptx Pb/C최화제최화양화갑산적성능우우상업Pt/C최화제적최화성능,차수Pt화Pb원자비적영향,당원자비위5:1시,기대양화갑산적최화성능최호,봉전위대응적Pt적비질량활성체도2000 mA/( mg Pt),원원고우상업Pt/C,동시계시전류곡선표명기구비량호적은정성。결론 Pb원자적가입영향료Pt원자적전자결구,여Pb대Pt적협동작용공동촉진료CO등중간산물재Pt표면적쾌속양화,강저료최화양화갑산적초시전위,촉사갑산재저전위직접양화위CO2화H2 O,제고료기최화양화갑산적봉전류,유효감경료Pt중독,제고료기최화활성。
ABSTRACT:Objective To improve the electro-oxidation catalytic performance of Pt/C catalyst for formic acid by adding the Pb element. Methods The Ptx Pb/C catalysts with different atomic ratios were prepared by an ethylene glycol-assisted NaBH4 reduction method. The structure and morphology of the catalyst were characterized by X-ray diffraction ( XRD) and transmission electron mi-croscopy ( TEM) , electrochemical performances were investigated by cyclic voltammetry. All electrochemical measurements were carried out in a conventional three-electrode electrochemical cell at 25 ℃ using cyclic voltammetry (CV) on a CHI 760B. Results The results of XRD and TEM showed that all prepared catalysts displayed typical character of Pt face center cubic phase with an av-erage size of Pt nanoparticles at 4 nm which had an uniform dispersion on carbon support. The Ptx Pb/C catalysts had better electro-catalytic activity for formic acid electrocatalytic oxidation than that of JM-Pt/C. The electro-catalytic activity was affected by the a-tomic ratios of Pt and Pb. In addition, when the atomic ratio was 5 : 1, the PtxPb/C catalyst showed the highest peak current den-sity ( mass activity) of 2000 mA/mg Pt with better stability. Conclusion The adding of Pb atoms affects the electronic structure of Pt atoms. With the assistance of Pb to Pt, the rapid oxidation, such as CO, is promoted the intermediate products on the surface of Pt. In addition, the synergistic effect reduce the initial electric potential of catalyzing oxidation formic acid, promote formic acid di-rectly oxidated as CO2 and H2 O, improve the peak current of catalyzing oxidation formic acid, effectively deduce the poisoning of Pt, and enhance its catalytic activity.
