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Sputtered Ultrathin WO<sub>3</sub> for Realizing Room-Temperature High-Sensitive NO<sub>2</sub> Gas Sensors

Yu-Chuan Chiu, Moumita Deb, Po‐Tsun Liu, Hsiao‐Wen Zan, Yun-Ru Shih, Yue Kuo, Dun‐Bao Ruan, Kai‐Jhih Gan, Chih-Chieh Hsu

2023ACS Applied Electronic Materials27 citationsDOI

Abstract

In this work, we used a commercial manufacturing process to obtain a WO 3 semiconductor gas sensor to realize NO 2 detection in parts-per-billion concentration at room temperature (25–27 °C). The radio-frequency (RF) sputtering process was used to deposit an ultrathin (down to 5 nm) WO 3 sensing layer. With suitable control of the deposition ambient and the postannealing condition, the WO 3 ultrathin-film resistor with a 50-μm line width can detect 100 ppb of NO 2 without any heating setup. Notably, no nanometer process is required; hence, the production can be realized by current flat-panel display technology. By modulating the deposition condition, we investigated the influences of surface roughness, crystalline condition, and surface hydroxyl group levels on the sensing response. To achieve parts-per-billion (ppb) level detection, the ultrathin thickness is essential, and the high-level crystal together with the low-level surface hydroxyl group also enhances the sensitivity and the recovery. The humidity effect is also discussed to show an almost unchanged response in relative humidity (RH) from 30 to 70%. In summary, the WO 3 sensor shows good sensing performance, including a high sensitivity, a wide detecting concentration range (17 ppm to 100 ppb), and fast response/recovery (30 s/∼21 s) at low NO 2 concentration (0.68 ppm). Finally, the good enough selectivity, stability, and nondecayed sensing of the WO 3 -based gas sensor after 14 days were demonstrated.

Topics & Concepts

Materials scienceRelative humiditySputteringSurface roughnessHumiditySurface finishParts-per notationOptoelectronicsNanometreAnalytical Chemistry (journal)Deposition (geology)Sensitivity (control systems)NanotechnologyThin filmComposite materialChemistryElectronic engineeringMeteorologyOrganic chemistryEngineeringPhysicsBiologyPaleontologySedimentChromatographyGas Sensing Nanomaterials and SensorsAnalytical Chemistry and SensorsAdvanced Chemical Sensor Technologies
Sputtered Ultrathin WO<sub>3</sub> for Realizing Room-Temperature High-Sensitive NO<sub>2</sub> Gas Sensors | Litcius