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
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.