物理化学学报
物理化學學報
물이화학학보
ACTA PHYSICO-CHIMICA SINICA
2014年
2期
318-324
,共7页
徐莉%潘国顺%梁晓璐%罗桂海%邹春莉%罗海梅
徐莉%潘國順%樑曉璐%囉桂海%鄒春莉%囉海梅
서리%반국순%량효로%라계해%추춘리%라해매
非贵金属催化剂%双杂化%热处理%碱性燃料电池%氧还原反应
非貴金屬催化劑%雙雜化%熱處理%堿性燃料電池%氧還原反應
비귀금속최화제%쌍잡화%열처리%감성연료전지%양환원반응
Non-noble metal catalyst%Dual-dopant%Heat-treatment%Alkaline fuel cel%Oxygen reduction reaction
通过溶剂分散热处理方法制备了一种吡咯和对甲苯磺酸(TsOH)共同修饰的碳载非贵金属复合催化剂(Fe-N/C-TsOH),并采用扫描电子显微镜(SEM)、X射线衍射(XRD)和X射线光电子能谱(XPS)对催化剂的形貌和组成成分进行表征.借助循环伏安法(CV)和旋转圆盘技术研究了TsOH对催化剂在0.1 mol?L-1 KOH介质中催化氧还原性能的影响.结果表明:TsOH的存在对催化剂催化氧还原反应(ORR)的活性影响很大.以其制备的气体扩散电极在碱性电解质溶液中催化氧还原过程时转移的电子数为3.899,远比不含TsOH修饰的催化剂催化氧还原的电子数(3.098)高.此外,研究发现600°C热处理过的Fe-N/C-TsOH催化剂表现出最佳的氧还原催化性能.相比未经热处理过的Fe-N/C-TsOH催化剂,起峰电位和-1.5 mA?cm-2电流密度对应的电压分别向正方向移动30和170 mV. XPS研究结果表明吡咯氮是催化剂主要活性中心,提供氧还原活性位,而TsOH加入形成的C-Sn-C和-SOn-有利于催化剂催化氧还原活性的提高,从而使该催化剂对氧还原表现出很好的电催化性能和选择性.
通過溶劑分散熱處理方法製備瞭一種吡咯和對甲苯磺痠(TsOH)共同脩飾的碳載非貴金屬複閤催化劑(Fe-N/C-TsOH),併採用掃描電子顯微鏡(SEM)、X射線衍射(XRD)和X射線光電子能譜(XPS)對催化劑的形貌和組成成分進行錶徵.藉助循環伏安法(CV)和鏇轉圓盤技術研究瞭TsOH對催化劑在0.1 mol?L-1 KOH介質中催化氧還原性能的影響.結果錶明:TsOH的存在對催化劑催化氧還原反應(ORR)的活性影響很大.以其製備的氣體擴散電極在堿性電解質溶液中催化氧還原過程時轉移的電子數為3.899,遠比不含TsOH脩飾的催化劑催化氧還原的電子數(3.098)高.此外,研究髮現600°C熱處理過的Fe-N/C-TsOH催化劑錶現齣最佳的氧還原催化性能.相比未經熱處理過的Fe-N/C-TsOH催化劑,起峰電位和-1.5 mA?cm-2電流密度對應的電壓分彆嚮正方嚮移動30和170 mV. XPS研究結果錶明吡咯氮是催化劑主要活性中心,提供氧還原活性位,而TsOH加入形成的C-Sn-C和-SOn-有利于催化劑催化氧還原活性的提高,從而使該催化劑對氧還原錶現齣很好的電催化性能和選擇性.
통과용제분산열처리방법제비료일충필각화대갑분광산(TsOH)공동수식적탄재비귀금속복합최화제(Fe-N/C-TsOH),병채용소묘전자현미경(SEM)、X사선연사(XRD)화X사선광전자능보(XPS)대최화제적형모화조성성분진행표정.차조순배복안법(CV)화선전원반기술연구료TsOH대최화제재0.1 mol?L-1 KOH개질중최화양환원성능적영향.결과표명:TsOH적존재대최화제최화양환원반응(ORR)적활성영향흔대.이기제비적기체확산전겁재감성전해질용액중최화양환원과정시전이적전자수위3.899,원비불함TsOH수식적최화제최화양환원적전자수(3.098)고.차외,연구발현600°C열처리과적Fe-N/C-TsOH최화제표현출최가적양환원최화성능.상비미경열처리과적Fe-N/C-TsOH최화제,기봉전위화-1.5 mA?cm-2전류밀도대응적전압분별향정방향이동30화170 mV. XPS연구결과표명필각담시최화제주요활성중심,제공양환원활성위,이TsOH가입형성적C-Sn-C화-SOn-유리우최화제최화양환원활성적제고,종이사해최화제대양환원표현출흔호적전최화성능화선택성.
Pyrolyzed carbon supported ferrum polypyrrole (Fe-N/C) catalysts were synthesized with and without the dopant p-toluenesulfonic acid (TsOH) through a solvent-grinding method followed by heat-treatment at the desire temperature. Both the catalysts were characterized using electrochemical techniques, such as cyclic voltammetry (CV), as wel as the rotating disk electrode (RDE) technique. It was found that the catalysts doped with TsOH showed significantly better oxygen reduction reaction (ORR) activity than the undoped catalysts. The average electron transfer numbers for the catalyzed ORR were 3.899 and 3.098 for the TsOH-doped and undoped catalysts, respectively. Thermal treatment was found to be a necessary step for catalyst activity improvement. The catalyst pyrolyzed at 600 ° C showed the best ORR activity: the onset potential and the potential at the current density of-1.5 mA?cm-2 for the TsOH-doped catalyst were 30 and 170 mV more positive than those for the un-pyrolyzed TsOH-doped catalyst, respectively. To clarify the effects of TsOH doping and pyrolyzation, scanning electron microscopy (SEM), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS) were used to analyze the morphology, structure, and composition of the catalysts. The XPS results suggest that the pyrrolic-N groups are the most active sites and sulfur species are structural y bound to carbon in the form of C-Sn-C and oxidized-SOn-bonds, which is an additional beneficial factor for the ORR.
