Gas sensing oxide materials and methods - past, present and future

G. Kale
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Abstract

Metal oxides in different length scales have been used as sensing materials for designing gas sensors for several years. A number of sensor architectures have been explored for developing selective gas sensors that are capable of discriminating between reducing and oxidising gases as well as amongst the gases that are either reducing or oxidising. There is an immense drive towards developing highly selective gas sensors for continuous environmental monitoring and in-line process control in both benign and hostile conditions. Some of the desirable essential features of a typical gas sensor are (1) the ability to discriminate between gases in a real mixture of gases at all temperatures, (2) fast response, (3) rapid recovery, (4) high sensitivity, (5) size, (6) manufacturability, (7) cost effectiveness, (8) signal reproducibility, (9) robustness of signal, (10) compatibility with data logging system and (11) wireless communication. Many of these aspects strongly depend on the synthetic chemistry, crystal structure, film thickness, particle size, porosity, morphology, composition and catalytic properties of the sensing material.This paper will attempt to illustrate how gas sensors research has evolved over the number of years with the advancement in physics and chemistry of materials and what does the future holds for the technology.
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气敏氧化物材料和方法——过去、现在和未来
近年来,不同长度尺度的金属氧化物被用作气体传感器的传感材料。已经探索了许多传感器架构,用于开发能够区分还原性和氧化性气体以及还原性或氧化性气体的选择性气体传感器。在良好和恶劣条件下,开发高选择性气体传感器用于连续环境监测和在线过程控制是一个巨大的动力。典型气体传感器的一些理想基本特征是:(1)能够在所有温度下区分真实气体混合物中的气体,(2)快速响应,(3)快速恢复,(4)高灵敏度,(5)尺寸,(6)可制造性,(7)成本效益,(8)信号可再现性,(9)信号鲁棒性,(10)与数据记录系统兼容,(11)无线通信。这些方面很大程度上取决于传感材料的合成化学、晶体结构、薄膜厚度、粒度、孔隙度、形貌、组成和催化性能。本文将试图说明气体传感器的研究是如何随着材料的物理和化学的进步而发展的,以及该技术的未来。
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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