AgNO3浓度对纳米银形态和结构的影响

稀有金属材料与工程, 2011, 40(2): 215-219.

AgNO3浓度对纳米银形态和结构的影响

周泽渊 ^1, , 于淑湘 ^2, , 林媛 ^3, , 张铭 ^4, , 蔡韩辉 ^5, , 商洪涛 ^6, , 何文喜 ^7,

1.第四军医大学,陕西,西安,710032

2.徐州解放军第97医院,江苏,徐州,210003

3.第四军医大学,陕西,西安,710032

4.第四军医大学,陕西,西安,710032

5.西北有色金属研究院,陕西,西安,710016

6.第四军医大学,陕西,西安,710032

7.第四军医大学,陕西,西安,710032

基金项目: National Science Foundation of China(50771077)

关键词：纳米Ag , 单晶枝晶 , AgNO3

Effect of AgNO3 Concentration on Morphologies and Structures of Nanostructured Ag

Zhou Zeyuan ^1, , Yu Shuxiang ^2, , Lin Yuan ^3, , Zhang Ming ^4, , Cai Hanhui ^5, , Shang Hongtao ^6, , He Wenxi ^7,

1.第四军医大学,陕西,西安,710032

2.徐州解放军第97医院,江苏,徐州,210003

3.第四军医大学,陕西,西安,710032

4.第四军医大学,陕西,西安,710032

5.西北有色金属研究院,陕西,西安,710016

6.第四军医大学,陕西,西安,710032

7.第四军医大学,陕西,西安,710032

Keywords： nanostructured Ag , dendrite , AgNO3

采用Zn置换AgN03溶液的方法制备具有不同形貌和结构的纳米AS,研究AgNO<,3>溶液的浓度对纳米Ag树枝生长速率、形貌和结构的影响.实验结果表明,纳米Ag树枝生长速率、形貌和结构主要取决于AgNO<,3>溶液的浓度和反应时间.纳米Ag树枝生长速率主要取决于AgNO<,3>溶液的浓度,浓度越高,生长速率越大.当AgNO<,3>溶液的浓度为5 mmol/L,反应初期的产物为Ag分形.随着时间延长,Ag分形转变为由纳米颗粒聚集而形成Ag枝晶.最后转变为单晶.当AgNO<,3>溶液浓度在20～100 mmol/L时,反应的产物均为.Ag枝晶,但加mmol/L以下浓度溶液中生成的Ag枝晶由纳米晶粒组成,而60 mmol/L以上浓度溶液中生成的Ag枝晶为单晶.通过控制AgNO<,3>溶液的浓度和反应时间,可制备具有不同形貌和结构的纳米Ag.

Nanostructured Ag with different morphologies and structures was prepared by replacement reaction(Zn versus AgNO<,3>).The influence of AgNO<,3> concentration on the growth speed, the morphology and the structure of the nanostructured Ag was investigated. Experimental results show that the growth speed, morphologies and structures of the nanostructured Ag strongly depend on AgNO<,3> concentration and reaction time. The growth speed is mainly dependent on the AgNO<,3> concentration; the higher the concentration, the faster the growth speed. When the AgNO<,3> concentration is 5 mmol/L, Ag fractal forms at the beginning stage,but the fractal transforms to dendrite consisting of nanoparticles and to monocrystal at last as the reaction proceeds. When the concentration is in the range of 20-100 retool/L, the products are all Ag dendrites, but the dendrites consist of nanoparticles when the concentration is below 40 mmol/L while they are monocrystal when the concentration is above 60 mmol/L. Ag nanostructures with different morphologies and structures can be prepared by controlling AgNO<,3> concentration and reaction time.

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