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Entropy-Stabilized Isolated Active Pd Species within a High-Entropy Fluorite Oxide Matrix for CO<sub>2</sub> Hydrogenation to Formic Acid

Kohsuke Mori, Yuki Shimada, Hideto Yoshida, Yoyo Hinuma, Hiromi Yamashita

2024ACS Applied Nano Materials9 citationsDOI

Abstract

Active, stable Pd species were incorporated within the matrix of fluorite-based high-entropy oxide (HEO) (YZrLaGdHf) x O 2 using an entropy-driven strategy based on a liquid-phase reaction. In situ X-ray absorption fine structure analyses and transmission electron microscopy observations at elevated temperatures under H 2 confirmed that partially aggregated Pd oxide species in the as-synthesized Pd@(YZrLaGdHf) x O 2 were transformed into an entropy-stabilized isolated form at 600 °C. In contrast, Pd species on the (YZrLaGdHf) x O 2 surface were readily reduced with the formation of nanoclusters/nanoparticles even in the temperature range of 100 to 200 °C. This Pd@(YZrLaGdHf) x O 2 exhibited enhanced activity during the hydrogenation of CO 2 to formic acid with a maximum turnover number of 5000 based on the quantity of surface-exposed Pd atoms. This performance was more than eight times higher than that of the Pd/(YZrLaGdHf) x O 2 on the basis of supported Pd. An assessment of the kinetics and theoretical investigations suggested that entropy-stabilized isolated Pd species facilitated both H 2 dissociation and the attack of dissociated H atoms on C atoms in HCO 3 – ions.

Topics & Concepts

FluoriteFormic acidOxideEntropy (arrow of time)ChemistryInorganic chemistryThermodynamicsMaterials scienceChromatographyOrganic chemistryPhysicsCarbon dioxide utilization in catalysisCatalytic Processes in Materials ScienceCatalysis and Oxidation Reactions
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