Correlated electron perovskite films for optical sensing applications

SPIE NanoScience + Engineering Pub Date : 2015-10-09 DOI:10.1117/12.2188924

A. Schultz, T. D. Brown, P. Ohodnicki

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引用次数: 3

Abstract

Advanced power generation technologies including solid oxide fuel cells require advancements in sensor technologies for efficient operation. Gas sensors for SOFC anode streams must be stable in high temperature and under reducing atmospheres. Optical sensing technologies offer the potential for good stability and sensing response under harsh conditions but are relatively new as compared to alternative sensing approaches and require significant developments in underlying device and enabling materials technology. In this paper, the near infrared optical sensing response of La0.8Sr0.2MnO3, a representative correlated perovskite material, is presented. Hydrogen sensing performance was measured in laboratory scale sensing experiments in the range of 1-4% hydrogen. The effect of oxygen on sensor recovery behavior was also examined. The films show a large, recoverable response to the introduction of hydrogen to the gas stream. The results presented here suggest this unique class of materials is a strong candidate for future sensor development efforts targeted at optical sensor applications but also requires additional fundamental research to understand the mechanistic origin of observed optical sensing responses.

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光学传感应用的相关电子钙钛矿薄膜

包括固体氧化物燃料电池在内的先进发电技术需要传感器技术的进步才能有效运行。用于SOFC阳极流的气体传感器必须在高温和还原气氛下保持稳定。光学传感技术在恶劣条件下具有良好的稳定性和传感响应的潜力，但与其他传感方法相比，光学传感技术相对较新，需要在基础设备和使能材料技术方面取得重大进展。本文研究了具有代表性的相关钙钛矿材料La0.8Sr0.2MnO3的近红外光学传感响应。在1-4%氢气浓度范围内进行了实验室尺度的氢气传感实验。研究了氧对传感器恢复性能的影响。这些薄膜显示了向气体流中引入氢的一个大的、可恢复的响应。这里提出的结果表明，这类独特的材料是未来针对光学传感器应用的传感器开发工作的有力候选材料，但也需要额外的基础研究来了解观察到的光学传感响应的机制起源。

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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SPIE NanoScience + Engineering

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