Low-Cost and High-Stable C-SiO2-PTFE Gas Diffusion Membrane for Ultrafast Electrochemical NO2 Sensor

IF 8 1区化学 Q1 CHEMISTRY, ANALYTICAL Sensors and Actuators B: Chemical Pub Date : 2024-11-23 DOI:10.1016/j.snb.2024.136997

Fengzhen Gao, Junxuan Liang, Faying Fan, Rui Wang, Benshuai Jiang, Kewei Zhang

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Abstract

Electrochemical gas sensors (EGSs) are the most effective means for detecting NO₂ gas in industry, while facing the issue of exorbitant cost due to the use of expensive Pt catalyst. Herein, well-dispersed C-SiO₂ into polytetrafluoroethylene (PTFE) was adopt as high-stable gas diffusion membrane for ultrafast electrochemical NO₂ sensors. The nano-SiO₂ not only prevents material aggregation but also constructs porous networks between the gas diffusion electrode and gas molecules, providing a larger sensing area for high sensor performance. The fabricated sensor exbibits excellent response linearity, short response time, and high stability. As compared with commercial Pt/C electrode, the sensor response is improved by 170%. Moreover, a multiple linear regression model was introduced to predict the response values of NO₂ in the range of 5-100 ppm, achieving only 1.5% deviation from the real values. This work not only demonstrates the feasibility of non-precious metals in gas diffusion membranes but also provides guide for designing next-generation low-cost EGSs.

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用于超快电化学二氧化氮传感器的低成本、高稳定性 C-SiO2-PTFE 气体扩散膜

电化学气体传感器（EGS）是工业领域检测二氧化氮（NO2）气体的最有效手段，但也面临着因使用昂贵的铂催化剂而导致成本过高的问题。本文采用在聚四氟乙烯（PTFE）中充分分散的 C-SiO2 作为超快电化学二氧化氮传感器的高稳定气体扩散膜。纳米二氧化硅不仅能防止材料聚集，还能在气体扩散电极和气体分子之间构建多孔网络，提供更大的传感面积，从而实现更高的传感器性能。所制备的传感器具有优异的响应线性、响应时间短和稳定性高等特点。与商用 Pt/C 电极相比，传感器的响应速度提高了 170%。此外，还引入了多元线性回归模型来预测 5-100 ppm 范围内的二氧化氮响应值，结果与实际值的偏差仅为 1.5%。这项工作不仅证明了非贵金属在气体扩散膜中的可行性，还为设计下一代低成本 EGS 提供了指导。

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来源期刊

Sensors and Actuators B: Chemical 工程技术-电化学

CiteScore

14.60

自引率

11.90%

发文量

1776

审稿时长

3.2 months

期刊介绍： Sensors & Actuators, B: Chemical is an international journal focused on the research and development of chemical transducers. It covers chemical sensors and biosensors, chemical actuators, and analytical microsystems. The journal is interdisciplinary, aiming to publish original works showcasing substantial advancements beyond the current state of the art in these fields, with practical applicability to solving meaningful analytical problems. Review articles are accepted by invitation from an Editor of the journal.