功能材料
功能材料
공능재료
JOURNAL OF FUNCTIONAL MATERIALS
2012年
10期
1281-1284
,共4页
聚吡咯%钒氧纳米管%复合材料%阴极材料%电化学性能
聚吡咯%釩氧納米管%複閤材料%陰極材料%電化學性能
취필각%범양납미관%복합재료%음겁재료%전화학성능
polypyrrole%vanadium oxide nanotubes%composites%cathodes%electrochemical performance
以V2O5粉末和过氧化氢为原料,十六烷基胺为模板剂,利用水热合成法制备钒氧纳米管,然后结合阳离子交换技术,用导电聚合物聚吡咯修饰替换钒氧纳米管中的有机模板剂,成功制备了聚吡咯/钒氧纳米管复合材料。借助透射电子显微镜和傅里叶红外光谱观察和分析了修饰前后纳米管的形貌和结构变化,实验结果证实聚吡咯不但成功修饰替换了钒氧纳米管中的有机模板剂,而且还很好地保持了纳米管的管状结构。采用恒流充放电和循环伏安分别测试了修饰前后样品的电化学性能,测试结果表明导电聚合物聚吡咯的修饰替换极大地提高了电极材料的首次充放电比容量和循环稳定性,循环伏安结果和20次循环后的表面形貌分析也进一步证实了这一结论。由于聚吡咯具有高的电导率和良好的柔韧性,不仅提高了复合纳米管材料的电导率,而且还改善了复合纳米管材料的结构稳定性。
以V2O5粉末和過氧化氫為原料,十六烷基胺為模闆劑,利用水熱閤成法製備釩氧納米管,然後結閤暘離子交換技術,用導電聚閤物聚吡咯脩飾替換釩氧納米管中的有機模闆劑,成功製備瞭聚吡咯/釩氧納米管複閤材料。藉助透射電子顯微鏡和傅裏葉紅外光譜觀察和分析瞭脩飾前後納米管的形貌和結構變化,實驗結果證實聚吡咯不但成功脩飾替換瞭釩氧納米管中的有機模闆劑,而且還很好地保持瞭納米管的管狀結構。採用恆流充放電和循環伏安分彆測試瞭脩飾前後樣品的電化學性能,測試結果錶明導電聚閤物聚吡咯的脩飾替換極大地提高瞭電極材料的首次充放電比容量和循環穩定性,循環伏安結果和20次循環後的錶麵形貌分析也進一步證實瞭這一結論。由于聚吡咯具有高的電導率和良好的柔韌性,不僅提高瞭複閤納米管材料的電導率,而且還改善瞭複閤納米管材料的結構穩定性。
이V2O5분말화과양화경위원료,십륙완기알위모판제,이용수열합성법제비범양납미관,연후결합양리자교환기술,용도전취합물취필각수식체환범양납미관중적유궤모판제,성공제비료취필각/범양납미관복합재료。차조투사전자현미경화부리협홍외광보관찰화분석료수식전후납미관적형모화결구변화,실험결과증실취필각불단성공수식체환료범양납미관중적유궤모판제,이차환흔호지보지료납미관적관상결구。채용항류충방전화순배복안분별측시료수식전후양품적전화학성능,측시결과표명도전취합물취필각적수식체환겁대지제고료전겁재료적수차충방전비용량화순배은정성,순배복안결과화20차순배후적표면형모분석야진일보증실료저일결론。유우취필각구유고적전도솔화량호적유인성,불부제고료복합납미관재료적전도솔,이차환개선료복합납미관재료적결구은정성。
Vanadium oxide nanotubes were firstly prepared by hydrothermal treatment, in which V2 O5 and H2O2 were used as raw materials and C16 H33 NH2 as structure-directing template. And then, polypyrrole/vanadium oxide nanotubes were synthesized by exchanging organic template with conducting polymer polypyrrole. TEM and FT-IR were employed to investigate the morphology and structure of the samples. The results confirm that the template was replaced by conducting polymer polypyrrole without destroying the previous nanotubular structure. Moreover, the electrochemical performance of the synthesized samples was tested by galvanostatic charge-discharge cycling and cyclic voltammetry. The results demonstrate that polypyrrole/vanadium oxide nanotubes had enhanced capacity and improved cycle stability, the improved electrochemical performance may be attributed to the incorporation of the conducting polymer polypyrrole.
