Phase-field simulation of self-healing AlMg alloy H. Sepúlveda1,∗, S. Fetni1, J. Delahaye2, J. Gheysen3, S. De Raedemacker4, J. Villanova5, L. Duchêne1, A. Simar4, A. M. Habraken1 1 University of Liège, UEE Research Unit, MSM division, allée de la Découverte, 9 B52/3, B 4000 Liège, Belgium 2 University of Liège, Place du 20-Août, 7, B 4000, Liège, Belgium 3 Laboratory of Mechanical Metallurgy, École Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzertland 4 Institute of Mechanics, Materials and Civil Engineering (iMMC), Université catholique de Louvain, B-1348 Louvain-la-Neuve, Belgium 5 ESRF – The European Synchrotron, Grenoble 38043, France ∗ H.sepulveda@doct.uliege.be Keywords: Phase-field model, Self-healing material, Diffusion healing heat treatment The AlMg alloys are widely used in different transportation industries due to their excellent strength-to-weight ratio [1]. In these industries, the components must withstand overloads and a high number of loading cycles [2], which, over time, can generate damage in the materials and in the worst-case failure [3]. To increase the lifetime of these parts, one innovative solution is to use self-healing materials. There exist different types of self-healing methods, one of them is the diffusion self-healing mechanism. In this mechanism, the alloy microstructure is composed of a healing agent in solid solution [4]. After damage, a healing heat treatment triggers the diffusion of this healing agent towards the voids and heals the material. An in-situ Diffusion Healing Heat Treatment at 400 °C was applied to heal a damaged AlMg alloy at the European Synchrotron Radiation Facility (ESRF) [5], where nano-holotomographies (nano-CT) of the damaged and healed microstructure evidenced the healing capacity of the alloy by diffusion mechanism with a voxel size of 35 nm. A diffusion phase-field model based on Kim-Kim-Suzuki [6] was applied to predict the microstructure evolution of the material during this healing heat treatment. The results obtained with the phase-field model are compared with the experimental measurements to corroborate their accuracy. References [1] Yi, G., Cullen, D. A., Littrell, K.C., Golumbfskie, W., Sundberg, E., Free, M.L. (2017). Characterization of Al-Mg alloy aged at low temperatures. Metall. Mater. Trans. A Phys. Metall. Mater. Sci., 48, 2040 – 2050. [2] Harlow, D. G., Nardiello, J., Payne, J. (2010). The effect of constituent particles in aluminium alloys on fatigue damage evolution: Statistical observations. Int. J. Fatigue, 32, 505 – 511. [3] Srivastava, V., Gupta, M. (2018). Approach to self healing in metal matrix composites: A review. Mater. Today Proc., 5, 19703 – 19713. [4] Arseenko, M., Gheysen, J., Hannard, F., Nothomb, N., Simar, A. (2022). “Self healing in Metal-Based systems.” Self-Healing construction materials. Springer, 2022, pp. 43 – 78. [5] De Raedemacker, S., Gheysen, J., Hannard, F., Nothomb, N., Pyka, G., Sepúlveda, H., & Simar, A. (2026). Investigation by 3D nano-imaging of the multiple healing ability and kinetics 93
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