Litcius/Paper detail

Redispersing Ir Nanoparticles via a Carbon-Assisted Pyrolysis Process to Break the Activity–Stability Trade-Off of H<sub>2</sub> Sensors

Mengmeng Guo, Xiaojie Li, Lingli Wang, Zhenggang Xue, Jiaqiang Xu

2024ACS Sensors17 citationsDOI

Abstract

Oxide semiconductor-supported metal nanoparticles often suffer from a high-temperature gas sensing process, resulting in agglomeration and coalescence, which significantly decrease their surface activity and stability. Here, we develop an in situ pyrolysis strategy to redisperse commercial Ir particles (∼15.6 nm) into monodisperse Ir species (∼5.4 nm) on ZnO supports, exhibiting excellent sintering-resistant properties and H 2 sensing. We find that large-size Ir nanoparticles can undergo an unexpected splitting decomposition process and spontaneously migrate along the encapsulated carbon layer surface during high-temperature pyrolysis of ZIF-8. This resultant monodisperse status can be integrally reserved, accompanying further oxidation sintering. The final Ir red /ZnO-450-based sensor exhibits outstanding stability, H 2 response (10–2000 ppm), fast response/recovery capability (7/9.7 s@100 ppm), and good moisture resistance. In situ Raman and ex situ XPS further experimentally verify that highly dispersive Ir species can promote the electron transfer process during the gas sensing process. Our strategy thus provides important insights into the design of agglomeration-resistant gas sensing materials for highly effective H 2 detection.

Topics & Concepts

PyrolysisEconomies of agglomerationNanoparticleMaterials scienceSinteringCoalescence (physics)DispersityChemical engineeringCarbon fibersNanotechnologyOxideMetallurgyComposite materialPolymer chemistryPhysicsEngineeringAstrobiologyComposite numberGas Sensing Nanomaterials and SensorsZnO doping and propertiesCatalytic Processes in Materials Science