Effect of Au nanoparticles on mitigating the negative impacts of humidity on ZnO gas sensors to detect triethylamine at room temperature

IF 7.5 Q1 CHEMISTRY, PHYSICAL
Amirhossein Alaghmandfard, Somayeh Fardindoost, Mina Hoorfar
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Abstract

The impact of humidity on the efficiency of gas sensors has become highlighted in the realm of gas detection. Due to the complex relationship between humidity and gas sensor performance, the development of gas sensors has recently focused on minimizing humidity-related interference. This research aims to address humidity-related challenges in zinc oxide (ZnO) gas sensors designed to detect triethylamine. The ZnO nanostructures (NSs) were synthesized using thermal decomposition methods at varying temperatures (380 °C, 480 °C, and 580 °C) and annealing times (3 h, 7 h, 12 h, and 21 h). X-ray diffraction (XRD) confirmed the formation of a wurtzite hexagonal close-packed structure in ZnO NSs. Scanning electron microscopy (SEM) images provided insights into the morphologies of ZnO NSs at different annealing temperatures, while energy dispersive spectroscopy (EDS) demonstrated the elemental distribution. Subsequently, gold (Au) nanoparticles were uniformly sputtered onto ZnO sensors with thickness variations (0.1 nm, 0.6 nm, 1 nm, 5 nm, and 10 nm). XPS was employed to analyse the elemental composition and oxygen vacancies of the synthesized sensing materials. The effectiveness of 0.6 nm-thick Au nanoparticles in mitigating humidity effects was observed in ZnO sensors synthesized at 380 °C. The results indicated that ZnO sensors coated with 0.6 nm-thick Au nanoparticles exhibited highly stable responses to ethanol and triethylamine at different humidity levels from 50 % to 90 %. Notably, these sensors demonstrated promising selectivity towards triethylamine (with a response of 17.57) compared to various gas targets at room temperature. The sensor exhibited rapid response and recovery times of 9.8 s and 4.4 s, respectively, toward triethylamine with excellent stability in variable humid environments. The sensor maintained a consistent response over 24 days, demonstrating good stability at high humidity.

金纳米粒子对减轻湿度对氧化锌气体传感器在室温下检测三乙胺的负面影响的影响
在气体检测领域,湿度对气体传感器效率的影响已成为一个突出问题。由于湿度与气体传感器性能之间的复杂关系,最近气体传感器的开发重点是最大限度地减少与湿度有关的干扰。本研究旨在解决设计用于检测三乙胺的氧化锌(ZnO)气体传感器中与湿度有关的难题。氧化锌纳米结构(NSs)是在不同温度(380 °C、480 °C和580 °C)和退火时间(3小时、7小时、12小时和21小时)下采用热分解方法合成的。X 射线衍射(XRD)证实 ZnO NSs 形成了钨六方紧密堆积结构。扫描电子显微镜(SEM)图像提供了不同退火温度下 ZnO NSs 的形态,而能量色散光谱(EDS)则显示了元素的分布。随后,金(Au)纳米粒子被均匀地溅射到厚度不同(0.1 nm、0.6 nm、1 nm、5 nm 和 10 nm)的氧化锌传感器上。利用 XPS 分析了合成传感材料的元素组成和氧空位。在 380 ℃ 合成的氧化锌传感器中观察到了 0.6 nm 厚的金纳米粒子在减轻湿度效应方面的有效性。结果表明,镀有 0.6 nm 厚金纳米粒子的氧化锌传感器在 50% 至 90% 的不同湿度水平下对乙醇和三乙胺的反应非常稳定。值得注意的是,与室温下的各种气体目标相比,这些传感器对三乙胺具有良好的选择性(响应为 17.57)。该传感器对三乙胺的快速响应和恢复时间分别为 9.8 秒和 4.4 秒,在多变的潮湿环境中具有出色的稳定性。该传感器在 24 天内保持了一致的响应,显示了在高湿度环境下的良好稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
8.10
自引率
1.60%
发文量
128
审稿时长
66 days
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