Quantitative Strain and Topography Mapping of 2D Materials Using Nanobeam Electron Diffraction.

IF 13.8 1区 计算机科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Journal on Selected Areas in Communications Pub Date : 2022-04-01 DOI:10.1017/S1431927622000502
Julian Sickel, Marcel Asbach, Christoph Gammer, Rudolf Bratschitsch, Helmut Kohl
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Abstract

It is known that 2D materials can exhibit a nonflat topography, which gives rise to an inherent strain. Since local curvature and strain influence mechanical, optical, and electrical properties, but are often difficult to distinguish from each other, a robust measurement technique is needed. In this study, a novel method is introduced, which is capable of obtaining quantitative strain and topography information of 2D materials with nanometer resolution. Relying on scanning nanobeam electron diffraction (NBED), it is possible to disentangle strain from the local sample slope. Using the positions of the diffraction spots of a specimen at two different tilts to reconstruct the locations and orientations of the reciprocal lattice rods, the local strain and slope can be simultaneously retrieved. We demonstrate the differences to strain measurements from a single NBED map in theory, simulation, and experiment. MoS2 monolayers with different shapes are used as simulation test structures. The slope and height information are recovered, as well as tensile and angular strain which have an absolute difference of less than 0.2% and 0.2° from the theoretical values. An experimental proof of concept using a freely suspended WSe2 monolayer together with a discussion of the accuracy of the method is provided.

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利用纳米束电子衍射绘制二维材料的定量应变和形貌图
众所周知,二维材料会呈现非平面形貌,从而产生固有应变。由于局部曲率和应变会影响机械、光学和电学特性,但往往难以相互区分,因此需要一种稳健的测量技术。本研究介绍了一种新方法,它能以纳米分辨率获取二维材料的定量应变和形貌信息。依靠扫描纳米束电子衍射(NBED),可以将应变与局部样品斜率分离开来。利用试样在两个不同倾斜度下的衍射点位置来重建倒易点阵杆的位置和方向,就能同时获得局部应变和斜率。我们展示了理论、模拟和实验中单一 NBED 图与应变测量的不同之处。我们使用不同形状的 MoS2 单层作为模拟测试结构。斜率和高度信息得以恢复,拉伸和角度应变与理论值的绝对差异也小于 0.2% 和 0.2°。实验证明了使用自由悬浮 WSe2 单层的概念,并讨论了该方法的准确性。
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来源期刊
CiteScore
30.00
自引率
4.30%
发文量
234
审稿时长
6 months
期刊介绍: The IEEE Journal on Selected Areas in Communications (JSAC) is a prestigious journal that covers various topics related to Computer Networks and Communications (Q1) as well as Electrical and Electronic Engineering (Q1). Each issue of JSAC is dedicated to a specific technical topic, providing readers with an up-to-date collection of papers in that area. The journal is highly regarded within the research community and serves as a valuable reference. The topics covered by JSAC issues span the entire field of communications and networking, with recent issue themes including Network Coding for Wireless Communication Networks, Wireless and Pervasive Communications for Healthcare, Network Infrastructure Configuration, Broadband Access Networks: Architectures and Protocols, Body Area Networking: Technology and Applications, Underwater Wireless Communication Networks, Game Theory in Communication Systems, and Exploiting Limited Feedback in Tomorrow’s Communication Networks.
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