Saved in:
Bibliographic Details
Main Authors: McKeown-Green, Amy S., Moradifar, Parivash, Zhang, Zisheng, Lim, Cedric, Barnum, Andrew, Yuan, Lin, Sinclair, Robert, Abild-Pedersen, Frank, Ophus, Colin, Dionne, Jennifer A.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.00433
Tags: Add Tag
No Tags, Be the first to tag this record!
Table of Contents:
  • Bimetallic catalysts provide new routes toward sustainable ammonia synthesis, but the structural dynamics controlling their performance under real-world conditions remain poorly understood. Here, we combine in situ gas-cell and multimodal electron microscopy to disentangle the temperature-, pressure-, and chemistry-dependent restructuring of AuRu catalysts, revealing pathways accessible only at atmospheric pressure. As synthesized, AuRu nanocatalysts are polycrystalline face-centered-cubic alloys with Au/Ru intermixing that phase-segregate into Au- and Ru-rich domains with elevated temperature (>450 °C). Increased pressure (~1 atm in 3:1, hydrogen:nitrogen) unlocks pronounced faceting and internal nanovoid formation, which systematic gas-chemistry variation identifies as hydrogen-driven. Density functional theory-based interatomic potentials show that hydrogen can amplify Au/Ru diffusion asymmetry, promoting nanovoid formation via a gas-mediated Kirkendall mechanism. Together, these results bridge the pressure gap between traditional in situ electron microscopy and benchtop ammonia reactors, enabling resolution of distinct restructuring stimuli in multicomponent systems.