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用测向力显微镜对力/电/热耦合作用下金表面力学行为的研究
引用本文:王权,丁建宁,薛伟,余朋清.用测向力显微镜对力/电/热耦合作用下金表面力学行为的研究[J].传感技术学报,2006,19(5A):1497-1499.
作者姓名:王权  丁建宁  薛伟  余朋清
作者单位:[1]江苏大学机械工程学院微纳米科学技术研究中心,江苏镇江212013 [2]温州大学工业工程学院,浙江温州323035
基金项目:浙江省科技攻关计划项目资助(2005C31048);江苏大学博士生创新基金项目资助
摘    要:对微构件力/电/热等多域场下力学行为的研究有着重要的意义,利用原子力显微镜采用纳米压痕法对样品金在力-电-热耦合作用下的表面力学性能进行了研究,实验表明在压痕过程中,无论在无电场作用下还是有电场作用下,压痕周围的金属由于挤压形成了凸起,从扫描得到的形貌图中可以明显的看出,压痕周围的亮区为材料被挤出的区域.此外,在外加直流电场作用下,随电流的增大,硬度值有增大的趋势,而残余压痕和弹性模量都呈现减小的趋势.

关 键 词:原子力显微镜  纳米压痕法  多域场耦合  力学行为
文章编号:1004-1699(2006)05-1497-03
收稿时间:2006-07-01

Au Surface Mechanical Behavior Research with Eiectro-Thermo-Mechanicai Coupled Action Using Atomic Force Microscope
WANG Quan, DING Jian-ning,XUE Wei, YU Peng-qing.Au Surface Mechanical Behavior Research with Eiectro-Thermo-Mechanicai Coupled Action Using Atomic Force Microscope[J].Journal of Transduction Technology,2006,19(5A):1497-1499.
Authors:WANG Quan  DING Jian-ning  XUE Wei  YU Peng-qing
Affiliation:1. Center of Micro/Nano Science and Technology, Jiangsu University, Zhenjiang Jiangsu 212013,China ; 2.Industrial Engineering School, Wenzhou University, Wenzhou Zhejiang 323035,China
Abstract:The mechanics problems can drastically compromise device performance and reliability. To solve these problems, there is a need to develop a fundamental understanding of mechanical behaviors of microstructures in MEMS. Au surface mechanical behavior is studied with electro-thermo-mechanical coupled action by using atomic force microscope. The experimental results show that some pile-ups of the metal around caused by indention were formed no matter whether the external electric field or not was applied in the process of the indention, in other words, the bright area around the indention hole which can be evidently seen from the scanned topographical image indicates the one where the materials were pushed out. Moreover, when the DC external electric field is applied, the hardness value of the tested sample presents an increase trend with the increment of electric current, but a decrease trend for the residue area and the elastic modulus.
Keywords:atomic force microscope  nanoindentation  coupling  mechanical properties
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