loading page

Enhanced Urea Oxidation Reaction through Layered Double Hydroxides: Insights from ZIF-67-Derived Nanostructures
  • +5
  • Yuri Jeon,
  • Jury Medvedev,
  • Yeeun Seong,
  • Xenia Medvedeva,
  • Cheongwon Bae,
  • Jeongeon Kim,
  • Anna Klinkova,
  • Juyeong Kim
Yuri Jeon
Gyeongsang National University
Author Profile
Jury Medvedev
University of Waterloo
Author Profile
Yeeun Seong
Gyeongsang National University
Author Profile
Xenia Medvedeva
University of Waterloo
Author Profile
Cheongwon Bae
Gyeongsang National University
Author Profile
Jeongeon Kim
Gyeongsang National University
Author Profile
Anna Klinkova
University of Waterloo
Author Profile
Juyeong Kim
Gyeongsang National University

Corresponding Author:[email protected]

Author Profile

Abstract

Layered double hydroxides (LDHs) are ionic layered compounds characterized by anion-containing intermediate regions within positively charged brucite-like layers. LDHs have shown high electrochemical activity in energy conversion systems such as batteries and fuel cells. In this study, we developed a hierarchically porous nanostructure derived from zeolitic imidazolate framework-67, which was subsequently transformed into an LDH structure with varying Ni concentrations. We precisely controlled the Ni-to-Co ratio within the LDH structure and investigated how different mole fractions of Co and Ni influence catalytic activity and selectivity for the electrochemical urea oxidation reaction (UOR). LDH structures with low Ni content (up to 40%) demonstrated high activity and selectivity for O 2 due to their structural instability and the predominant oxygen evolution reaction (OER) originating from ZIF-67. In contrast, LDHs with high Ni content (over 60%) supressed OER and exhibited enhanced activity for UOR. The resulting hollow structure with an expanded electrochemically active surface in LDHs with high Ni content could improve mass transport and diffusion at the electrode interface, leading to better reaction kinetics and higher current densities. These findings provide a foundational design guideline for metal–organic framework-derived nanostructure in UOR.
15 Oct 2024Submitted to EcoMat
15 Oct 2024Submission Checks Completed
15 Oct 2024Assigned to Editor
15 Oct 2024Review(s) Completed, Editorial Evaluation Pending
19 Oct 2024Reviewer(s) Assigned
29 Oct 2024Editorial Decision: Revise Major