Recent Progress of Metal/Nonmetal Nanowire Joining Technology and Its Applications

被引:0
|
作者
Zhang H. [1 ]
Wang S. [1 ]
Feng J. [1 ]
Ma J. [1 ]
Hu X. [1 ]
Feng Y. [1 ]
Tian Y. [1 ,2 ]
机构
[1] State Key Laboratory of Advanced Welding and Joining, Harbin Institute of Technology, Harbin
[2] Key Laboratory of Micro-systems and Micro-structures Manufacturing of Ministry of Education, Harbin Institute of Technology, Harbin
来源
Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2022年 / 58卷 / 02期
关键词
Flexible electronics; Heterogeneous joining; Homogeneous joining; Micro-nano devices; Nanowires joining;
D O I
10.3901/JME.2022.02.076
中图分类号
学科分类号
摘要
Micro-nano joining process is a key technique in the manufacturing, packaging, assembly and functionalization of electronic products. Because of its unique optical, electrical and thermal properties, nanowires are playing an increasingly important role in miniaturized and multifunctional micro-nano electronic devices. Therefore, the research on nanowire joining technology has become a common focus of both academia and industry. Compared with the macroscopic interconnection, the interconnection between nanowires has certain particularity in size, structure and requirements, which also gives rise to the birth and development of a variety of nanowire interconnection methods. This paper reviews the current metal/nonmetal nanowires research progress of homogeneous and heterogeneous connection, sums up the common methods of nanowires interconnection, such as thermal joining, light irradiation, electric auxiliary joining and high energy beam joining method and their mechanism, such as in flexible electronics and other applications in the field of micro-nano device packaging. The existing problems and development trend of metal/nonmetal nanowire joining technology are also discussed. © 2022 Journal of Mechanical Engineering.
引用
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页码:76 / 87
页数:11
相关论文
共 75 条
  • [41] ZHANG H, WANG S, HANG C, Et al., Joining of copper nanowires by electrodepositing silver layer for high-performance transparent electrode, Welding in the World, 65, pp. 1021-1030, (2021)
  • [42] SHEHLA H, ISHAQ A, KHAN Y, Et al., Ion beam irradiation-induced nano-welding of Ag nanowires, Micro & Nano Letters, 11, pp. 34-37, (2016)
  • [43] XU S, TIAN M, WANG J, Et al., Nanometer-scale modification and welding of silicon and metallic nanowires with a high-Intensity electron beam, Small, 1, pp. 1221-1229, (2005)
  • [44] PENG Y, CULLIS T, INKSON B., Bottom-up nanoconstruction by the welding of individual metallic nanoobjects using nanoscale solder, Nano Letters, 9, pp. 91-96, (2009)
  • [45] GAO F, GU Z., Nano-soldering of magnetically aligned three-dimensional nanowire networks, Nanotechnology, 21, (2010)
  • [46] LEE J, LEE P, LEE H B, Et al., Room-temperature nanosoldering of a very long metal nanowire network by conducting-polymer-assisted joining for a flexible touch-panel application, Advanced Functional Materials, 23, pp. 4171-4176, (2013)
  • [47] LIANG J, LI L, TONG K, Et al., Silver nanowire percolation network soldered with graphene oxide at room temperature and its application for fully stretchable polymer light-emitting diodes, ACS Nano, 8, pp. 1590-1600, (2014)
  • [48] HUANG Y, TIAN Y, HANG C, Et al., Self-limited nanosoldering of silver nanowires for high-performance flexible transparent heaters, ACS Applied Materials & Interfaces, 11, pp. 21850-21858, (2019)
  • [49] GU J, WANG X, CHEN H, Et al., Conductivity enhancement of silver nanowire networks via simple electrolyte solution treatment and solvent washing, Nanotechnology, 29, (2018)
  • [50] LIANG X, ZHAO T, JIANG W, Et al., Highly transparent triboelectric nanogenerator utilizing in-situ chemically welded silver nanowire network as electrode for mechanical energy harvesting and body motion monitoring, Nano Energy, 59, pp. 508-516, (2019)
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