Nature Communications (Jan 2024)

Impact of palladium/palladium hydride conversion on electrochemical CO2 reduction via in-situ transmission electron microscopy and diffraction

  • Ahmed M. Abdellah,
  • Fatma Ismail,
  • Oliver W. Siig,
  • Jie Yang,
  • Carmen M. Andrei,
  • Liza-Anastasia DiCecco,
  • Amirhossein Rakhsha,
  • Kholoud E. Salem,
  • Kathryn Grandfield,
  • Nabil Bassim,
  • Robert Black,
  • Georg Kastlunger,
  • Leyla Soleymani,
  • Drew Higgins

DOI
https://doi.org/10.1038/s41467-024-45096-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 15

Abstract

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Abstract Electrochemical conversion of CO2 offers a sustainable route for producing fuels and chemicals. Pd-based catalysts are effective for converting CO2 into formate at low overpotentials and CO/H2 at high overpotentials, while undergoing poorly understood morphology and phase structure transformations under reaction conditions that impact performance. Herein, in-situ liquid-phase transmission electron microscopy and select area diffraction measurements are applied to track the morphology and Pd/PdHx phase interconversion under reaction conditions as a function of electrode potential. These studies identify the degradation mechanisms, including poisoning and physical structure changes, occurring in PdHx/Pd electrodes. Constant potential density functional theory calculations are used to probe the reaction mechanisms occurring on the PdHx structures observed under reaction conditions. Microkinetic modeling reveals that the intercalation of *H into Pd is essential for formate production. However, the change in electrochemical CO2 conversion selectivity away from formate and towards CO/H2 at increasing overpotentials is due to electrode potential dependent changes in the reaction energetics and not a consequence of morphology or phase structure changes.