Revealing the Chemical State of Palladium in Operating In2O3 Gas Sensors: Metallic Pd Enhances Sensing Response and Intermetallic InxPdy Compound Blocks It

The sensing response of metal oxides activated with noble metal nanoparticles is significantly influenced by changes to the chemical state of corresponding elements under operating conditions. Here, a PdO/rh-In2O3 consisting of PdO nanoparticles loaded onto rhombohedral In2O3 was studied as a gas sensor for H-2 gas (100-40000 ppm in an oxygen-free atmosphere) in the temperature range of 25-450 degrees C. The phase composition and chemical state of elements were examined by resistance measurements combined with synchrotron-based in situ X-ray diffraction and ex situ X-ray photoelectron spectroscopy. As found, PdO/rh-In2O3 undergoes a series of structural and chemical transformations during operation: from PdO to Pd/PdHx and finally to the intermetallic InxPdy phase. The maximal sensing response (R-N2/R-H2) of similar to 5 center dot 10(7) towards 40000 ppm (4 vol %) H-2 at 70 degrees C is correlated with the formation of PdH0.706/Pd. The InxPdy intermetallic compounds formed around 250 degrees C significantly decrease the sensing response.

Automated summary

The sensing response of metal oxides activated with noble metal nanoparticles is affected by changes in the chemical state of the elements. In this study, a PdO/rh-In2O3 gas sensor was investigated for H2 gas detection. The composition and chemical state of elements were examined during operation. It was found that the sensor showed a series of structural and chemical transformations, leading to a decrease in sensing response.