用于氟化氢气体检测的6D-4石英上的广义和纯剪切水平SAW传感器

B. Meulendyk, M. C. Wheeler, B. Segee, M. Pereira da Cunha
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引用次数: 3

摘要

氟化氢(HF)是一种用于各种工业过程的有害化合物,是许多其他含氟挥发性有机化合物(voc)的分解产物,这些化合物通常是环境污染物。石英衬底上的表面声波(SAW)谐振器适合于HF传感,因为分析物可以直接与传感器衬底反应产生H2O和挥发性化合物SiF4,后者从表面蒸发。这项工作表明,在气相HF暴露于广义SAW (GSAW)谐振器和纯剪切水平SAW (SHSAW)谐振器时,主要的传感机制是检测衬底表面的冷凝液体层,而不是通过SiF4解吸去除材料。分别在ST-X和ST-900石英上制备的GSAW和SHSAW通过小体积(~1 cm)测试池同时暴露于HF中。这些设备的反应被监控,每分钟收集一次数据。自动化气体输送系统用于改变HF浓度从1- 18ppm,同时保持恒定的流量为100似乎。虽然两种谐振器都对凝聚液体层的形成很敏感,但对于所研究的HF浓度,由于这种影响,SHSAW谐振器的频移比GSAW装置的频移大7倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
6D-4 Generalized and Pure Shear Horizontal SAW Sensors on Quartz for Hydrogen Fluoride Gas Detection
Hydrogen fluoride (HF) is a hazardous compound used in a variety of industrial processes and is a decomposition product of many other fluorinated volatile organic compounds (VOCs), which are often environmental contaminants. Surface acoustic wave (SAW) resonators on quartz substrates are suited for HF sensing because the analyte can react directly with the sensor substrate to produce H2O and the volatile compound SiF4, which evaporates from the surface. This work shows evidence that during gas phase HF exposure to a generalized SAW (GSAW) resonator and a pure shear horizontal SAW (SHSAW) resonator, the dominant sensing mechanism is the detection of a condensed liquid layer on the substrate surface, rather than material removal via SiF4 desorption. The GSAW and SHSAW, fabricated on ST-X and ST-900 quartz, respectively, have been simultaneously exposed to HF through a low-volume (~1 cm ) test cell. The devices' responses were monitored, with data collected every minute. An automated gas delivery system was used to vary HF concentrations from 1-18 ppm, while maintaining a constant flow rate of 100 seem. While both resonators are sensitive to the formation of a condensed liquid layer, the frequency shift of the SHSAW resonator, due to this effect, is up to seven times greater than that of the GSAW device for the HF concentrations investigated.
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