设计用于室温 H2S 传感的 NiO-ZnCo2O4 异质结构

IF 1.8 4区 物理与天体物理 Q3 PHYSICS, APPLIED Modern Physics Letters B Pub Date : 2024-05-31 DOI:10.1142/s0217984924504098
Ali Akhtar, Rujun Zhou, Daru Chen, Shama Sadaf, Ce Fu, Jianqiao Liu
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引用次数: 0

摘要

硫化氢(H2S)检测具有新颖的传感特性,如更高的响应和室温下的最低检测限,这对于确保人类和环境的安全至关重要。研究人员采用水热法合成了 NiO-ZnCo2O4 异质结构。这些材料的目的是制造气体传感器,检测不同的有害气体。研究人员对合成产品的内在特性进行了研究,以检查异质结构的微观结构和形态特性。不同的气体传感器具有不同的气体传感特性,其中显著的特性包括:对 20ppm H2S 的高响应(气体中的响应与空气中的响应之比 Rg∕Ra=290)、短响应/恢复时间(32/20 秒)、低检测限(0.NZCO-5 (5% NiO-ZnCo2O4) 气体传感器与其他 NiO、NZCO-0 (0% NiO-ZnCo2O4) 和 NZCO-10 (10% NiO-ZnCo2O4) 传感器相比,检测到了 5 ppm 的 H2S,并具有很高的选择性。)这项研究在 H2S 气体传感方面的重大改进可能是拯救人类生命的潜在途径。
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Design of NiO–ZnCo2O4 heterostructures for room temperature H2S sensing

Hydrogen sulfide (H2S) detection with novel sensing properties such as higher response and minimum detection limit at room temperature is essential to ensure the safety of humans and the environment. A hydrothermal method was utilized to synthesize NiO–ZnCo2O4 heterostructures. The purpose of these materials was to fabricate gas sensors and detect different hazardous gases. The intrinsic properties of synthesized products were studied to check the microstructure and morphological properties of the heterostructures. Different gas sensors performed gas sensing properties, and the significant properties such as high response (ratio of response in gas and response in air RgRa=290) towards 20ppm H2S, short response/recovery time (32/20 s), a low detection limit (0.5 ppm), and great selectivity were detected based on the gas sensor of NZCO-5 (5% NiO–ZnCo2O4) compared with other sensors NiO, NZCO-0 (0% NiO–ZnCo2O4) and NZCO-10 (10% NiO–ZnCo2O4). The significant H2S gas sensing improvement in this study could be a potential route for saving human lives.

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来源期刊
Modern Physics Letters B
Modern Physics Letters B 物理-物理:凝聚态物理
CiteScore
3.70
自引率
10.50%
发文量
235
审稿时长
5.9 months
期刊介绍: MPLB opens a channel for the fast circulation of important and useful research findings in Condensed Matter Physics, Statistical Physics, as well as Atomic, Molecular and Optical Physics. A strong emphasis is placed on topics of current interest, such as cold atoms and molecules, new topological materials and phases, and novel low-dimensional materials. The journal also contains a Brief Reviews section with the purpose of publishing short reports on the latest experimental findings and urgent new theoretical developments.
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