The project was focused in two types of alloys (Al and Mg) of very large industrial interest. The activities of the project were structured along two parallel pillars, namely virtual processing and virtual testing. The first achievement of the VIRMETAL project was to establish a cascade of modelling tools to predict the microstructure of cast Al-Cu alloys beginning by first principles simulations. The microstructural predictions were validated in all cases with ad hoc experiments and they were also extended to Mg alloys. The second achievement was to predict the critical resolved shear stress for dislocation motion in Al-Cu, Mg-Al and Mg-Zn alloys with different precipitates through the application of another cascade of modelling tools. Moreover, the experimental validation of the critical resolved shear stress for dislocation motion and twin nucleation and growth in single crystals of different Al and Mg alloys was achieved by means of nanomechanical testing techniques, which provided a novel strategy to obtain the bulk properties of metals as a function of composition and temperature. Finally, the mechanical properties (strength, fatigue life) of polycrystals were obtained by means of crystal plasticity models and computational homogenization of representative volume elements of the microstructure.
In addition, the expertise acquired within the project in alloy design has been used to design and manufacture new metallic alloys by selective laser melting and the micro- and nano-mechanical testing techniques developed during the project have been used to assess the mechanical properties of novel metal/ceramic and metal/metal nanolaminates, particularly at high temperature.
From the viewpoint of knowledge transfer, the research project VIRMETAL has led -so far- to > 50 publications in international peer-reviewed journals (including Science, Acta Materialia, Journal of the Mechanics and Physics of Solids, Nano Letters, etc) and four doctoral theses. Moreover, another three doctoral theses are very much advanced and will be defended by the end of 2021 or beginning of 2022. The scientific results of the research project have been disseminated through 50 plenary/keynote lectures in international conferences and 42 seminars, delivered as a result of invitations by universities and research centers throughout the world. Moreover, technology transfer of the results has been mainly accomplished through the license of CAPSUL- Crystal Plasticity simulation, a software package developed by J. Segurado, J. LLorca, V. Herrera-Solaz, A. Cruzado, S. Lucarini, S. Hauoala with support from the VIRMETAL project. The software is registered and has been licensed to MSC Software Belgium in 2019. CAPSUL is included in Digimat, the platform for materials simulation of e-Xstream engineering, a division of MSC Software Belgium S. A.