An integrated push-to-pull micromechanical device: Design, fabrication, and in-situ experiment

IF 4.3 3区 工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Extreme Mechanics Letters Pub Date : 2024-09-11 DOI:10.1016/j.eml.2024.102228
Jie Wang , Dihan Yao , Rong Wang , Zhiqiang Gao , Mengxiong Liu , Xuan Ye , Xide Li
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Abstract

The rapid advancement of micro-nano machining technology has led to a decrease in the dimensions of microdevices and microchips, following the principles of Moore’s law. In addition to conventional semiconductor materials like silicon, emerging nanoscale materials such as nanowires, nanotubes, and two-dimensional materials are being considered as promising alternative constituent materials. The mechanical properties of these materials have a significant impact on the performance and service life of these microdevices and microchips. However, conventional mechanical testing methods have difficulty in accurately measuring the properties of these materials at the nanoscale due to limitations in displacement control and microforce sensing. Consequently, there is an urgent need to develop a micromechanical device capable of testing nanoscale solid materials. In this study, we propose a concept based on high-resolution image sequences for the design of an integrated micromechanical device capable of synchronously measuring the force and deformation of tested specimens. The device has been fabricated using ultrafast femtosecond laser etching technology, which offers an efficient and cost-effective approach for manufacturing microstructures and is suitable for processing various materials such as metals and nonmetals. The stiffness of the device plays a crucial role in the design of the micromechanical device, and a stiffness-matching criterion is introduced to ensure appropriate design parameters. The fabricated device is employed to conduct in-situ tension experiments on SiC nanowires and multilayer molybdenum disulfide nanosheet within a scanning electronic microscope, enabling accurate measurement of their strength, modulus, and fracture strain.

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一体化推拉微机械装置:设计、制造和现场实验
微纳加工技术的飞速发展导致微器件和微芯片的尺寸按照摩尔定律的原则不断缩小。除了硅等传统半导体材料外,纳米线、纳米管和二维材料等新兴纳米级材料也被认为是很有前途的替代组成材料。这些材料的机械性能对这些微器件和微芯片的性能和使用寿命有重大影响。然而,由于位移控制和微力传感方面的限制,传统的机械测试方法难以在纳米尺度上准确测量这些材料的特性。因此,迫切需要开发一种能够测试纳米级固体材料的微机械装置。在本研究中,我们提出了一种基于高分辨率图像序列的概念,用于设计一种能够同步测量被测试样的力和变形的集成微机械装置。该装置采用超快飞秒激光蚀刻技术制造,该技术为制造微结构提供了一种高效且经济的方法,适用于加工金属和非金属等各种材料。装置的刚度在微机械装置的设计中起着至关重要的作用,因此引入了刚度匹配准则,以确保适当的设计参数。利用制作的装置在扫描电子显微镜下对碳化硅纳米线和多层二硫化钼纳米片进行了原位拉伸实验,从而精确测量了它们的强度、模量和断裂应变。
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来源期刊
Extreme Mechanics Letters
Extreme Mechanics Letters Engineering-Mechanics of Materials
CiteScore
9.20
自引率
4.30%
发文量
179
审稿时长
45 days
期刊介绍: Extreme Mechanics Letters (EML) enables rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.
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