Abstract
Exsolution has emerged as an outstanding route for producing oxide-supported metal nanoparticles. For ABO3-perovskite oxides, various late transition-metal cations can be substituted into the lattice under oxidizing conditions and exsolved as metal nanoparticles after reduction. A consistent and comprehensive description of the point-defect thermodynamics and kinetics of this phenomenon is lacking, however. Herein, supported by hybrid density-functional-theory calculations, we propose a single model that explains diverse experimental observations, such as why substituent transition-metal cations (but not host cations) exsolve from perovskite oxides upon reduction; why different substituent transition-metal cations exsolve under different conditions; why the metal nanoparticles are embedded in the surface; why exsolution occurs surprisingly rapidly at relatively low temperatures; and why the reincorporation of exsolved species involves far longer times and much higher temperatures. Our model’s foundation is that the substituent transition-metal cations are reduced to neutral species within the perovskite lattice as the Fermi level is shifted upward within the bandgap upon sample reduction. The calculations also indicate unconventional influences of oxygen vacancies and A-site vacancies. Our model thus provides a fundamental basis for improving existing, and creating new, exsolution-generated catalysts.
Original language | English |
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Pages (from-to) | 23012-23021 |
Journal | Journal of the American Chemical Society |
Volume | 146 |
Issue number | 33 |
Early online date | 8 Aug 2024 |
DOIs | |
Publication status | Published - 21 Aug 2024 |
Funding
This project has received funding: from the European Union\u2019s Horizon 2020 research and innovation program under grant agreement no 101017709 (EPISTORE); from the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)\u2500463184206 (SFB 1548, FLAIR: Fermi Level Engineering Applied to Oxide Electroceramics); and from EPSRC under grant EP/R023603/1. We gratefully acknowledge stimulating discussions with J. Polfus, and computing time from the NHR Center NHR4CES at RWTH Aachen University (project number p0020909). This is funded by the Federal Ministry of Education and Research, and the state governments participating on the basis of the resolutions of the GWK for national high performance computing at universities ( www.nhr-verein.de/unsere-partner ).
Funders | Funder number |
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Fermi Level Engineering Applied | |
Bundesministerium für Bildung und Forschung | |
Horizon 2020 Framework Programme | 101017709 |
Deutsche Forschungsgemeinschaft | 463184206, SFB 1548 |
Engineering and Physical Sciences Research Council | EP/R023603/1 |
ASJC Scopus subject areas
- Catalysis
- General Chemistry
- Biochemistry
- Colloid and Surface Chemistry