湿度环境下的高速、亚ppm 检测碲烯二氧化氮化学电阻室温传感器

IF 2.1 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Electronic Materials Letters Pub Date : 2024-09-11 DOI:10.1007/s13391-024-00520-0

Yeonjin Je, Sang-Soo Chee

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引用次数: 0

摘要

由碲组成的二维材料碲因其优越的内在导电性和对二氧化氮的强亲和力，已成为一种很有前途的二氧化氮气体传感材料。然而，有关碲基气体传感器的大多数文献主要关注干燥条件下的二氧化氮检测性能，尽管考虑湿度相关检测特性对于实际气体传感应用非常重要。在此，我们探讨了碲基化学电阻式气体传感器装置在室温湿度环境下的二氧化氮检测性能。通过水热法合成的碲烯呈现出二维片状形态，具有高度结晶的六边形结构。在干燥条件下，所获得的碲烯化学电阻传感器装置对 35% 的二氧化氮气体具有良好的响应，响应时间短，仅为 14 秒。有趣的是，我们的碲基传感器器件在实现快速响应时间的同时，还具有与湿度无关的二氧化氮气体检测性能。这些出色的检测性能可能是由于碲在空气中固有的优异导电性和结构稳定性。

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High-speed and Sub-ppm Detectable Tellurene NO2 Chemiresistive Room-Temperature Sensor under Humidity Environments

Two-dimensional material, tellurium, composed of tellurium, has emerged as a promising material for NO₂ gas sensing due to its superior intrinsic electrical conductivity and strong affinity to NO₂. However, the majority of literature on tellurene-based gas sensors has primarily focused on NO₂ detection performances under dry condition, despite the importance of considering humidity-dependent detection properties for practical gas sensing applications. Here, we explore NO₂ detection properties of tellurene-based chemiresistive gas sensor devices under humidity environments at room temperature. The resultant tellurene synthesized via a hydrothermal route presents 2D flake-like morphologies with highly crystalline hexagonal structures. The obtained tellurene chemiresistive sensor devices exhibit a good NO₂ gas response of 35% with a fast response time of 14 s, under dry conditions. Interestingly, our tellurene-based sensor devices also present the humidity-independent NO₂ gas detection performances while achieving a fast response time. These outstanding detection performances are likely due to intrinsically superior electrical conductivity and structural stability of tellurene in air.

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来源期刊

Electronic Materials Letters 工程技术-材料科学：综合

CiteScore

4.70

自引率

20.80%

发文量

审稿时长

2.3 months

期刊介绍： Electronic Materials Letters is an official journal of the Korean Institute of Metals and Materials. It is a peer-reviewed international journal publishing print and online version. It covers all disciplines of research and technology in electronic materials. Emphasis is placed on science, engineering and applications of advanced materials, including electronic, magnetic, optical, organic, electrochemical, mechanical, and nanoscale materials. The aspects of synthesis and processing include thin films, nanostructures, self assembly, and bulk, all related to thermodynamics, kinetics and/or modeling.