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Highly enhanced room-temperature single-atom catalysis of two-dimensional organic-inorganic multiferroics Cr(half-fluoropyrazine)2 for CO oxidation

Feixiang Zhang, Panshuo Wang, Yandi Zhu, Jinlei Shi, Rui Pang, Xiaoyan Ren, Shunfang Li

2025Nature Communications10 citationsDOIOpen Access PDF

Abstract

In modern chemistry, the development of highly efficient room-temperature catalysts is of great significance and remains a long-standing challenge in various typical reactions. Here, we theoretically demonstrate that the two-dimensional (2D) multiferroic, Cr(half-fluoropyrazine)2 [Cr(h-fpyz)2], is a promising single-atom catalyst (SAC) operating at room temperature for CO oxidation. The rate-limiting barrier is merely 0.325 eV, leading to a reaction rate (i.e., 3.47 × 106 s−1) of six orders of magnitude higher than its monoferroic derivative [Cr(pyz)2], due to the synergetic effects of two aspects. First, the more flexible ligand rotations in Cr(h-fpyz)2 facilitate the activation of O2 molecule, simultaneously enhancing the charge transfer and spin-accommodation process. Second, on Cr(h-fpyz)2, O2 adsorption induces a distinctly lower local positive electric field, reducing the electrostatic repulsion of the polar CO molecule. These findings may also pave the way for establishing highly efficient SAC platforms based on 2D multiferroics where multidegree of freedom (e.g., spin, polarity) synergistically matter. Developing energy efficient catalysts capable of performing at moderate temperatures is an important goal. Here the authors theoretically demonstrate that a 2D multiferroic, Cr(half-fluoropyrazine)2, acts as a promising single atom catalyst for CO oxidation at room temperature.

Topics & Concepts

MultiferroicsCatalysisAtom (system on chip)Materials scienceNanotechnologyChemical engineeringChemistryOptoelectronicsOrganic chemistryComputer scienceFerroelectricityEngineeringDielectricEmbedded system2D Materials and ApplicationsAdvanced Photocatalysis TechniquesCatalytic Processes in Materials Science