银纳米结构的固相合成及其光学、电化学性能(英文)

Solid-Phase Preparation and Optical,Electrochemical Properties of Silver Nanostructured Materials

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摘要本文以硝酸银和抗坏血酸为原料,通过简单的室温固相路线快速合成了银纳米结构.TEM观察显示,表面活性剂对银纳米结构的形貌存在重要的影响:无任何表面活性剂存在时,只能获得团聚的银纳米粒子;十二烷基硫酸钠用作表面活性剂时,获得由银纳米粒子组装的纳米棒;而十六烷基三甲基溴化铵作表面活性剂时,可获得一些银纳米线.同时,不同的银纳米结构其光学、电化学性能也不相同:在UV-Vis光谱中,团聚的银纳米粒子的吸收峰位置分别在270nm和465nm;银纳米棒的吸收峰分别位置分别在284nm和442nm,且前者弱,后者强;银纳米线则只在274nm处有一强的吸收峰。而在电化学响应中,团聚的银纳米粒子、纳米线和纳米棒的氧化、还原峰分别出现在0.396V和0.307V、0.087V和-0.045V、0.422V和0.324V. A solid-phase route was used for fast preparation of silver nanostructures employing AgNO3 and VC （L-Aseorbie acid） as reactants. TEM observations showed that the aggregated Ag nanoparticles were prepared in the absence of any surfactant; Ag nanorods were obtained when SDS was used and nanowires were produced in the presence of CTAB. The optical property of Ag nanostructures was influenced by different suffactants. When no suffactant was used, two absorption peaks, a narrow one at 270 nm and a widened one centered at 465 nm, appeared in the UV-Vis absorption spectrum of the product; after CTAB was used, the two peaks shifted to 284nm and 442nm, respectively. Simultaneously, the former weakened and the latter enhanced; After SDS was used instead of CTAB, the widened peak badly weakened and the narrow one at 274nm enhanced. Similarly, the electrochemical property of Ag nanostructures could be tuned by their shapes.

作者吴国艮洪建明倪永红胡广志杨周生叶寅

机构地区安徽师范大学化学与材料科学学院南京大学现代分析中心

出处《安徽师范大学学报（自然科学版）》 CAS 2008年第6期556-561,共6页 Journal of Anhui Normal University(Natural Science)

基金 Supported by National Natural Science Foundation of China(20771005 and 20571002) Science and Technological Fund of Anhui Province for Outstanding Youth(08040106834) the Education Department of Anhui Province(No.2006KJ006TD).

关键词金属纳米结构固相制备电化学性能 metals nanostructures solid-phase preparation electrochemical property

分类号 O164 [理学—基础数学]

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参考文献25

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安徽师范大学学报（自然科学版）

2008年第6期

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银纳米结构的固相合成及其光学、电化学性能(英文)

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