The proposed research project focuses on enhancing sustainability in aluminum alloy production through digital methods for optimizing composition-process-structure-property (CPSP) relationships. The secondary raw material route for aluminum alloys is particularly important for both industry and society to pave the way for a green future. Despite advances in separation technologies, reproducing exact alloy mixtures and avoiding impurities in the material cycle remains a challenge. This necessitates the design of impurity-resistant alloys suited to current material flows, along with tailored lean alloys for long-term sustainability. To address this challenge, CPSP relationships must be modeled using data from multiscale characterization techniques, employing physics-based approaches to represent thermo-chemo-mechanical coupling phenomena, followed by optimization using machine learning for materials design. The integration of advanced correlative microscopy techniques, such as atom probe tomography supports the modelling tasks by providing data and enhance the understanding of the CPSP relationships. Correlative microscopy with aluminum alloys, becomes possible with new cryo-FIB (focused ion beam) approaches, allowing for a deeper understanding of CPSP relationships in aluminum alloys.

DFG Programme Priority Programmes

Subproject of SPP 2489:  DaMic - Data-driven alloy and microstructure design of sustainable structural metals

International Connection USA

Cooperation Partners Professor Surya R. Kalidindi, Ph.D.; Professor Dr. Ji-Cheng Zhao