Broad-range, high-linearity, and fast-response pressure sensing enabled by nanomechanical resonators based on 2D non-layered material: β-In2S3

IF 22.7 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Infomat Pub Date : 2024-05-19 DOI:10.1002/inf2.12553

Junzhi Zhu, Song Wu, Luming Wang, Jiaqi Wu, Jiankai Zhu, Luwei Zou, Fei Xiao, Ziluo Su, Chenyin Jiao, Shenghai Pei, Zejuan Zhang, Jiaze Qin, Bo Xu, Yu Zhou, Juan Xia, Zenghui Wang

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Abstract

Two-dimensional (2D) non-layered materials, along with their unique surface properties, offer intriguing prospects for sensing applications. Introducing mechanical degrees of freedom is expected to enrich the sensing performances of 2D non-layered devices, such as high frequency, high tunability, and large dynamic range, which could lead to new types of high performance nanosensors. Here, we demonstrate 2D non-layered nanomechanical resonant sensors based on β-In₂S₃, where the devices exhibit robust nanomechanical vibrations up to the very high frequency (VHF) band. We show that such device can operate as pressure sensor with broad range (from 10⁻³ Torr to atmospheric pressure), high linearity (with a nonlinearity factor as low as 0.0071), and fast response (with an intrinsic response time less than 1 μs). We further unveil the frequency scaling law in these β-In₂S₃ nanomechanical sensors and successfully extract both the Young's modulus and pretension for the crystal. Our work paves the way towards future wafer-scale design and integrated sensors based on 2D non-layered materials.

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基于二维非层状材料：β-In2S3 的纳米机械谐振器实现宽范围、高线性度和快速响应压力传感

二维（2D）非层状材料及其独特的表面特性为传感应用提供了引人入胜的前景。引入机械自由度有望丰富二维非分层器件的传感性能，如高频率、高可调性和大动态范围，这将带来新型高性能纳米传感器。在这里，我们展示了基于 β-In2S3 的二维非层状纳米机械谐振传感器，该器件表现出高达甚高频（VHF）频段的稳健纳米机械振动。我们的研究表明，这种器件可用作压力传感器，具有范围广（从 10-3 托到大气压）、线性度高（非线性系数低至 0.0071）和响应速度快（固有响应时间小于 1 μs）的特点。我们进一步揭示了这些 β-In2S3 纳米机械传感器的频率缩放规律，并成功提取了晶体的杨氏模量和预拉力。我们的工作为未来基于二维非层状材料的晶圆级设计和集成传感器铺平了道路。

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来源期刊

Infomat MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

37.70

自引率

3.10%

发文量

111

审稿时长

8 weeks

期刊介绍： InfoMat, an interdisciplinary and open-access journal, caters to the growing scientific interest in novel materials with unique electrical, optical, and magnetic properties, focusing on their applications in the rapid advancement of information technology. The journal serves as a high-quality platform for researchers across diverse scientific areas to share their findings, critical opinions, and foster collaboration between the materials science and information technology communities.