High optical response NiO, Pd/NiO and Pd/WO3 hydrogen sensors

In this study, NiO and WO3 oxide semiconductors were fabricated on glass substrates by RF Magnetron Sputtering technique. Structural and optical characterizations of the semiconductors were performed using XRD, SEM, and optical absorption measurements. NiO and WO3 thin films were occasionally coated with palladium. In order to investigate the optical response of these semiconductors under hydrogen gas exposure, an optical gas sensor test system was installed and programmed. In both of the coated and uncoated cases, optical absorption changes due to hydrogen gas exposure on the surface were investigated. It was observed that these changes occur between 450 and 850 nm wave lengths range. The absorption in the NiO semiconductor was reduced between these wave lengths, while the absorption was increased in the WO3 semiconductor. In the uncoated state, only NiO gave an optical response to hydrogen gas. While the palladium coated NiO (Pd/NiO) sensor had the best response and recovery times of respectively 70 s and 206 s for 2% fraction of H-2 gas at 300 degrees C constant temperature, the Pd/WO3 sensor gave the best response time of 340 s. Palladium coating resulted in approximately 150% increase in the responses of the NiO sensors at higher H-2 concentration. The lower limit of H-2 sensing of the Pd/NiO sensors at 300 degrees C was at the H-2 fraction of 0.05%, while for Pd/WO3 sensors this value was 0.025%. (C) 2022 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

In this study, NiO and WO3 oxide semiconductors were prepared on glass substrates using RF Magnetron Sputtering technique and their structural and optical properties were characterized. The optical responses of these semiconductors to hydrogen gas were investigated and it was found that they exhibited different optical absorption changes in the wavelength range of 450-850 nm. Palladium coating significantly improved the response and recovery times of NiO sensors and increased their response to high concentrations of H-2 gas by approximately 150%.