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Revealing the Epitaxial Interface between Al<sub>13</sub>Fe<sub>4</sub> and Al<sub>5</sub>Fe<sub>2</sub> Enabling Atomic Al Interdiffusion

Corentin Chatelier, Kanika Anand, P. Gille, Marie-Cécile de Weerd, J. Ledieu, V. Fournée, Andrea Resta, Alina Vlad, Y. Garreau, Alessandro Coati, Émilie Gaudry

2023ACS Applied Materials & Interfaces15 citationsDOIOpen Access PDF

Abstract

Steel is the most commonly manufactured material in the world. Its performances can be improved by hot-dip coating with the low weight aluminum metal. The structure of the Al∥Fe interface, which is known to contain a buffer layer made of complex intermetallic compounds such as Al 5 Fe 2 and Al 13 Fe 4, is crucial for the properties. On the basis of surface X-ray diffraction, combined with theoretical calculations, we derive in this work a consistent model at the atomic scale for the complex Al 13 Fe 4 (010)∥Al 5 Fe 2 (001) interface. The epitaxial relationships are found to be [130] Al 5 Fe 2 ∥[010] Al 13 Fe 4 and [1 1̅0] Al 5 Fe 2 ∥[100] Al 13 Fe 4 . Interfacial and constrained energies, as well as works of adhesion, calculated for several structural models based on density functional theory, identify the lattice mismatch and the interfacial chemical composition as main factors for the stability of the interface. Molecular dynamics simulations suggest a mechanism of Al diffusion to explain the formation of the complex Al 13 Fe 4 and Al 5 Fe 2 phases at the Al∥Fe interface.

Topics & Concepts

Materials scienceIntermetallicEpitaxyAtomic unitsDiffractionAluminiumDiffusionMetalLattice (music)Density functional theoryChemical physicsAtomic diffusionLayer (electronics)CrystallographyAlloyMetallurgyThermodynamicsNanotechnologyComputational chemistryOpticsChemistryAcousticsPhysicsQuantum mechanicsSurface and Thin Film PhenomenaAdvanced Chemical Physics StudiesQuasicrystal Structures and Properties