基于电化学加工方法的铝基超疏水表面制备技术研究

中国机械工程 ›› 2011, Vol. 22 ›› Issue (19): 2354-2359.

基于电化学加工方法的铝基超疏水表面制备技术研究

徐文骥1;窦庆乐1;孙晶1;宋金龙1;庞桂兵2

1.大连理工大学,大连,116024

2.大连工业大学,大连,116034

出版日期:2011-10-10 发布日期:2011-10-12
基金资助:
国家自然科学基金重大研究计划资助项目(90923022)；国家自然科学基金资助项目(50905020)
Major Research Program of National Natural Science Foundation of China（No. 90923022）
National Natural Science Foundation of China（No. 50905020）

Study on Fabrication of Superhydrophobic Surface Substrate Based on ECM

Xu Wenji1;Dou Qingle1;Sun Jing1;Song Jinlong1;Pang Guibing2

1.Dalian University of Technology,Dalian,Liaoning,116024

2.Dalian Polytechnic University,Dalian,Liaoning,116034

Online:2011-10-10 Published:2011-10-12
Supported by:

Major Research Program of National Natural Science Foundation of China（No. 90923022）
National Natural Science Foundation of China（No. 50905020）

摘要/Abstract

摘要：

鉴于金属铝表面存在微米级的晶界和纳米级的位错,在外加电场和电解液的作用下,晶界位错处因具有更高的位能会使得阳极优先溶解,进而形成微纳米结构相结合的粗糙表面,提出一种新的铝基超疏水表面的电化学制备方法,实验研究了其加工质量、加工效率和加工条件之间的关系,结果显示电化学加工方法能够在铝基底上制备出多阶层微/纳米结构,可用作超疏水表面基底。电化学加工比化学刻蚀法有更好的可控性,同时比光刻等方法更经济。所加工表面经过低表面能材料修饰后呈现超疏水的特性,与水滴的接触角达到167°,滚动角小于3°。

关键词:

电化学加工, 超疏水表面, 微/纳米结构, 晶界, 位错

Abstract:

A new method of fabrication superhydrophobic surface by means of ECM was developed. The fabrication mechanism was based on the fact that the grain boundaries/dislocations were micro/nano-scale and more likely to be anodic dissolved than that of grain self, so the multi-scale micro/nano-structures surface can be generated by an applied electric field and the chemical solution. The relationship among processing quality, efficiency and conditions was studied in experiments herein.The results show that ECM can be used to fabricate dual-scale micro/nano-structures on aluminum surfaces, and further applied to generate the large size of superhydrophobic surface. The method is easier to control the reaction process than chemical etching meanwhile more economical than other techniques. After modified with low surface energy materials, the surface exhibits superhydrophobic property with water contact angle of 167° and tilt angle less than 3°.

Key words: electrochemical machining(ECM), superhydrophobic surface, micro/nano-structure, grain boundary, dislocation

中图分类号:

TG66

徐文骥1, 窦庆乐1, 孙晶1, 宋金龙1, 庞桂兵2.

基于电化学加工方法的铝基超疏水表面制备技术研究

[J]. 中国机械工程, 2011, 22(19): 2354-2359.

XU Wen-Ji-1, DOU Qiang-Le-1, SUN Jing-1, SONG Jin-Long-1, LONG Gui-Bing-2.

Study on Fabrication of Superhydrophobic Surface Substrate Based on ECM

[J]. China Mechanical Engineering, 2011, 22(19): 2354-2359.

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