Complexions at the iron-magnetite interface

Zhou, Xuyang; Bienvenu, Baptiste; Wu, Yuxiang; Silva, Alisson Kwiatkowski da; Ophus, Colin; Raabe, Dierk

Complexions at the iron-magnetite interface

Xuyang Zhou (), Baptiste Bienvenu (), Yuxiang Wu, Alisson Kwiatkowski da Silva, Colin Ophus and Dierk Raabe ()
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Xuyang Zhou: Max-Planck-Institut for Sustainable Materials (Max-Planck-Institut für Eisenforschung)
Baptiste Bienvenu: Max-Planck-Institut for Sustainable Materials (Max-Planck-Institut für Eisenforschung)
Yuxiang Wu: Max-Planck-Institut for Sustainable Materials (Max-Planck-Institut für Eisenforschung)
Alisson Kwiatkowski da Silva: Max-Planck-Institut for Sustainable Materials (Max-Planck-Institut für Eisenforschung)
Colin Ophus: Lawrence Berkeley National Laboratory
Dierk Raabe: Max-Planck-Institut for Sustainable Materials (Max-Planck-Institut für Eisenforschung)

Nature Communications, 2025, vol. 16, issue 1, 1-12

Abstract: Abstract Synthesizing distinct phases and controlling crystalline defects are key concepts in materials design. These approaches are often decoupled, with the former grounded in equilibrium thermodynamics and the latter in nonequilibrium kinetics. By unifying them through defect phase diagrams, we can apply phase equilibrium models to thermodynamically evaluate defects—including dislocations, grain boundaries, and phase boundaries—establishing a theoretical framework linking material imperfections to properties. Using scanning transmission electron microscopy (STEM) with differential phase contrast (DPC) imaging, we achieve the simultaneous imaging of heavy Fe and light O atoms, precisely mapping the atomic structure and chemical composition at the iron-magnetite (Fe/Fe3O4) interface. We identify a well-ordered two-layer interface-stabilized phase state (referred to as complexion) at the Fe[001]/Fe3O4[001] interface. Using density-functional theory (DFT), we explain the observed complexion and map out various interface-stabilized phases as a function of the O chemical potential. The formation of complexions increases interface adhesion by 20% and alters charge transfer between adjacent materials, impacting transport properties. Our findings highlight the potential of tunable defect-stabilized phase states as a degree of freedom in materials design, enabling optimized corrosion protection, catalysis, and redox-driven phase transitions, with applications in materials sustainability, efficient energy conversion, and green steel production.

Date: 2025
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DOI: 10.1038/s41467-025-58022-y

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