Smarter Dopant Design Unlocks High-Performance Ceria Catalysts for Oxygen Release and Soot Combustion

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Published in Chemistry and Materials

Smarter Dopant Design Unlocks High-Performance Ceria Catalysts for Oxygen Release and Soot Combustion
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In this work, we present a systematic investigation of Ce-site-substituted mixed oxides to establish a rational strategy for enhancing oxygen release in ceria-based materials. By combining different classes of dopants in a fluorite CeO₂ lattice, we identify clear dopant synergy effects that significantly lower oxygen-release temperatures and improve catalytic combustion performance. We further demonstrate that a carefully designed quaternary oxide, CePrZrSmOx, achieves both the highest oxygen-release capacity and the best soot-combustion activity among all the materials investigated.

Key Insights

  • Three dopant roles identified: reducible cations (Pr, Tb), lattice stabilizers (Zr, Ti), and oxygen-vacancy promoters (Sm, La).
  • Distinct enhancement mechanisms: dopants improve oxygen release through redox participation, enhanced Ce reducibility, or accelerated oxygen diffusion.
  • Synergy matters: combining dopants from different categories lowers oxygen-release temperatures more effectively than single-dopant systems.
  • Best-performing composition: the quaternary oxide CePrZrSmOx exhibited the lowest oxygen-release temperature (~428 °C) and highest oxygen-release capacity (~1.4 mmol g⁻¹).
  • Superior soot combustion: oxygen-release performance directly correlated with catalytic activity, with CePrZrSmOx achieving the lowest soot-combustion temperature (346 °C).
  • Rational design strategy: dopant synergy provides a practical framework for developing advanced oxygen-storage and combustion catalysts.

Significance of This Work

We establish a dopant-synergy design principle for ceria-based mixed oxides by linking reducibility, lattice stabilization, and oxygen-vacancy formation to oxygen-release performance. The resulting quaternary oxide demonstrates how complementary dopant functions can be combined to achieve superior catalytic properties.

These findings offer a rational pathway for developing high-performance combustion catalysts for emissions control and environmental applications, while also providing broader insights into the design of multicomponent oxide materials.

Authors & Affiliations

Duanxing Li, Fang Zhang, Yuki Nakaya, and Shinya Furukawa*
Division of Applied Chemistry, Graduate School of Engineering, The University of Osaka, Suita 565-0871, Osaka, Japan.

Corresponding Author:
Prof. Shinya Furukawa
furukawa@chem.eng.osaka-u.ac.jp

How to Cite This Article

Li, D. et al. (2026). Rational design of Ce-based mixed oxides via dopant synergy for enhanced oxygen release and combustion. Catal, 2, 15.

https://doi.org/10.1007/s44422-026-00027-9

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