| 柔性基周期性厚度梯度薄膜的应变效应 |
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| 引用本文: | 李会华,张嘉辉,余森江,卢晨曦,李领伟.柔性基周期性厚度梯度薄膜的应变效应[J].物理学报,2021(1):329-340. |
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| 作者姓名: | 李会华 张嘉辉 余森江 卢晨曦 李领伟 |
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| 作者单位: | 杭州电子科技大学材料与环境工程学院;杭州电子科技大学机械工程学院;中国科学技术大学近代力学系 |
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| 基金项目: | 国家自然科学基金(批准号:91963123);浙江省万人计划(批准号:2018R52003);浙江省属高校基本科研业务费专项资金(批准号:GK199900299012-022,GK209907299001-014)资助的课题. |
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| 摘 要: | 可控的表面微结构在柔性电子、仿生器件和能源材料等方面均具有重要的应用价值.本文采用编织铜网作为掩模板,利用磁控溅射技术在柔性聚二甲基硅氧烷(PDMS)基底上制备具有周期分布的厚度梯度金属银薄膜,研究了薄膜在单轴压缩/拉伸过程中的形貌演化规律.实验发现,在单轴机械载荷作用下,银薄膜表面将形成相互垂直的条纹褶皱和多重裂纹.膜厚的梯度变化调制了薄膜的面内应力分布,导致褶皱在膜厚较小处率先形成,并逐渐扩展到膜厚较大区域,而裂纹则基本限定在膜厚较小区域.基于应力理论和有限元计算,对周期性厚度梯度薄膜的褶皱和裂纹的形貌特征、演化行为和物理机制进行了深入分析.该研究将有助于加深对非均匀薄膜体系的应变效应的理解,并有望通过梯度薄膜的结构设计在柔性电子等领域获得应用.
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| 关 键 词: | 柔性电子 薄膜 厚度梯度 应变效应 |
Strain effects of periodic thickness-gradient films on flexible substrates |
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| Li Hui-Hua,Zhang Jia-Hui,Yu Sen-Jiang,Lu Chen-Xi,Li Ling-Wei.Strain effects of periodic thickness-gradient films on flexible substrates[J].Acta Physica Sinica,2021(1):329-340. |
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| Authors: | Li Hui-Hua Zhang Jia-Hui Yu Sen-Jiang Lu Chen-Xi Li Ling-Wei |
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| Affiliation: | (Key Laboratory of Novel Materials for Sensor of Zhejiang Province,College of Materials and Environmental Engineering,Hangzhou Dianzi University,Hangzhou 310018,China;School of Mechanical Engineering,Hangzhou Dianzi University,Hangzhou 310018,China;CAS Key Laboratory of Mechanical Behavior and Design of Materials,Department of Modern Mechanics,University of Science and Technology of China,Hefei 230026,China) |
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| Abstract: | Controlled surface structures have important applications in the fields of flexible electronics,bionic devices,smart materials and surface engineering.Although various instability modes induced by stresses in homogeneous and heterogeneous film systems have been investigated extensively in the past decades,understanding the stress relief mechanisms of gradient film systems is still a challenge.In this work,periodic thickness-gradient metal silver films on flexible polydimethylsiloxane(PDMS)substrates are prepared by using magnetron sputtering technique and by masking weaved copper grid during deposition.The morphological evolutions and structural characteristics of the gradient films in the uniaxial mechanical compression/tension process are detected by using optical microscopy and atomic force microscopy.It is found that the thickness-gradient film spontaneously forms on the PDMS surface due to the specific three-dimensional structure of the weaved copper grid.The maximum film thickness in the mesh center is about twice larger than the minimum one in the region covered by the copper wire.Under the uniaxial mechanical loading,the silver film surface will form stripe wrinkles and straight cracks,which are aligned perpendicular to each other.The variation of film thickness can well modulate the in-plane strain distribution of the film and thus the stress relief patterns.As the compressive strain increases,the wrinkles first form in the region with smaller film thickness,and then extend into the region with larger thickness.The wrinkle wavelength decreases with compressive strain increasing,which is in consistent with the theoretical prediction of accordion model.The wavelength and amplitude of the wrinkles exhibit periodically oscillatory behaviors across the film surface.As the tensile strain increases,the cracks start to propagate in the region with smaller thickness,and then the crack width and number both increase gradually,leading the multiple crack modes to form finally.The crack width and average spacing both increase with film thickness increasing.The morphologies and evolutions of such wrinkles and cracks in the thickness-gradient films are analyzed in depth based on the stress theory.The wrinkle patterns are further simulated by the finite element method,and the simulation results are in good agreement with the experimental results.This study could promote a better understanding of the strain effects of heterogeneous film systems and find the applications in the field of flexible electronics by the structural design of thickness-gradient films. |
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| Keywords: | flexible electronics film thickness-gradient strain effect |
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