Paper-Based Hydrogen Sensors Using Ultrathin Palladium Nanowires.
Abhishek KumarKaiwen ChenThomas ThundatMark T SwihartPublished in: ACS applied materials & interfaces (2023)
Hydrogen (H 2 ), as a chemical energy carrier, is a cleaner alternative to conventional fossil fuels with zero carbon emission and high energy density. The development of fast, low-cost, and sensitive H 2 detection systems is important for the widespread adoption of H 2 technologies. Paper is an environment-friendly, porous, and flexible material with great potential for use in sustainable electronics. Here, we report a paper-based sensor for room-temperature H 2 detection using ultrathin palladium nanowires (PdNWs). To elucidate the sensing mechanism, we compare the performance of polycrystalline and quasi-single-crystalline PdNWs. The polycrystalline PdNWs showed a response of 4.3% to 1 vol % H 2 with response and recovery times of 4.9 and 10.6 s, while quasi-single-crystalline PdNWs showed a response of 8% to 1 vol % H 2 with response and recovery times of 9.3 and 13.0 s, respectively. The polycrystalline PdNWs show excellent selectivity, stability, and sensitivity, with a limit of detection of 10 ppm H 2 in air. The fast response of ultrathin polycrystalline PdNW paper-based sensors arises from the synergistic effects of their ultrasmall diameter, high-index surface facets, strain-coupled grain boundaries, and porous paper substrate. This paper-based sensor is one of the fastest chemiresistive H 2 sensors reported and is potentially orders of magnitude less expensive than current state-of-the-art H 2 -sensing solutions. This brings low-cost, room-temperature chemiresistive H 2 sensing closer to the performance of ultrafast optical sensors and high-temperature metal oxide-based sensors.