物理化学学报
物理化學學報
물이화학학보
ACTA PHYSICO-CHIMICA SINICA
2012年
1期
85-89
,共5页
尹诗斌%罗林%荆胜羽%朱强强%强颖怀
尹詩斌%囉林%荊勝羽%硃彊彊%彊穎懷
윤시빈%라림%형성우%주강강%강영부
催化剂%交替微波加热法%旋转圆盘电极%氧还原反应%多壁碳纳米管
催化劑%交替微波加熱法%鏇轉圓盤電極%氧還原反應%多壁碳納米管
최화제%교체미파가열법%선전원반전겁%양환원반응%다벽탄납미관
Catalyst%Intermittent microwave heating method%Rotating disk electrode%Oxygen reduction reaction%Multi-walled carbon nanotube
详细研究了交替微波加热法制备多壁碳纳米管负载Pt催化剂(Pt/MWCNTs)的过程中交替微波加热(5s-on/5s-off)次数对催化剂性能的影响.X射线粉末衍射(XRD)结果表明,Pt的晶粒尺寸在开始的加热阶段基本上没有发生变化,但是随着加热次数的增多,Pt的晶粒尺寸逐步增大.采用循环伏安法和旋转圆盘电极技术考察了催化剂的电化学活性.结果显示,以5s-on/5s-off加热20次时,催化剂显示出最佳的催化活性;在0.5mol· L-1 H2SO4饱和氧水溶液中催化剂的氧还原起峰电位接近1.0 V(vs RHE).交替微波加热法简单经济,在大批量制备催化剂等纳米材料方面显示出较好的应用前景.
詳細研究瞭交替微波加熱法製備多壁碳納米管負載Pt催化劑(Pt/MWCNTs)的過程中交替微波加熱(5s-on/5s-off)次數對催化劑性能的影響.X射線粉末衍射(XRD)結果錶明,Pt的晶粒呎吋在開始的加熱階段基本上沒有髮生變化,但是隨著加熱次數的增多,Pt的晶粒呎吋逐步增大.採用循環伏安法和鏇轉圓盤電極技術攷察瞭催化劑的電化學活性.結果顯示,以5s-on/5s-off加熱20次時,催化劑顯示齣最佳的催化活性;在0.5mol· L-1 H2SO4飽和氧水溶液中催化劑的氧還原起峰電位接近1.0 V(vs RHE).交替微波加熱法簡單經濟,在大批量製備催化劑等納米材料方麵顯示齣較好的應用前景.
상세연구료교체미파가열법제비다벽탄납미관부재Pt최화제(Pt/MWCNTs)적과정중교체미파가열(5s-on/5s-off)차수대최화제성능적영향.X사선분말연사(XRD)결과표명,Pt적정립척촌재개시적가열계단기본상몰유발생변화,단시수착가열차수적증다,Pt적정립척촌축보증대.채용순배복안법화선전원반전겁기술고찰료최화제적전화학활성.결과현시,이5s-on/5s-off가열20차시,최화제현시출최가적최화활성;재0.5mol· L-1 H2SO4포화양수용액중최화제적양환원기봉전위접근1.0 V(vs RHE).교체미파가열법간단경제,재대비량제비최화제등납미재료방면현시출교호적응용전경.
The influence of intermittent microwave heating (IMH) on the physicochemical and electrochemical properties of platinum loaded on multi-walled carbon nanotubes (Pt/MWCNTs) was investigated.X-ray diffraction results revealed that the crystal size of Pt particles hardly increased for smaller numbers of pulse repetitions,but became much larger as the number of pulse repetitions increased.Cyclic voltammetry (CV) and rotating disk electrode (RDE) results showed that the Pt/MWCNTs catalysts prepared by IMH in a repeated pulse form of 5s-on/5s-off for 20 pulse repetitions possessed the largest electrochemical surface area.An onset potential of approximately 1.0 V (vs RHE) was observed for the oxygen reduction reaction in oxygen-saturated 0.5 mol· L-1 H2SO4 aqueous solutions.The IMH method is simple,economical,and can potentially be scaled up for the mass production of nanomaterials.
