INTERNATIONAL CAE CONFERENCE AND EXHIBITION
2017, 6 - 7 November
LIONoso for Materials Design Amir Mosavi, and Timon Rabczuk Institute of Structural Mechanics, Bauhaus University of Weimar, Germany Email: amir.mosavi@uni-weimar.de
Summary The software package of LIONoso [1], developed by LIONlab, is a comprehensive Machine Learning and Intelligent Optimization tool for non-profit research and academic use. The Learning and intelligent optimization (LION) [2] techniques enable problem-specific solvers with vast potential applications in industry and business. LIONoso is the ideal tool for the rapid development and implementation of LION techniques and advanced prescriptive analytics. Here we demonstrate such potentials for materials design innovation and further represent a use case in this context. The LIONoso is proposed as an adaptive solver toolbox for the virtual optimal design and simulation of innovative materials to model the fundamental properties and behaviour of a wide range of multi-scale materials design problems. The research on material design innovation is crucial for the long-lasting success of any technological sector and industry and it is a rapidly evolving field of challenges and opportunities aiming at development and application of multi-scale methods to simulate, predict and select innovative materials with high accuracy.
Keywords LIONoso, Machine Learning, Optimization, Material Design
Computational Materials Design Innovation Computational material design innovation is a new paradigm in which the usual route of materials selection is enhanced by concurrent materials design simulations and computational applications. Designing new materials is a multi-dimensional problem where multiple criteria of design need to be satisfied. Consequently material design innovation would require advanced multiobjective optimization (MOO) and decision-support tools. In addition the performance and behaviour of new materials must be predicted in different design scenarios and conditions. In fact predictive analytics and MOO algorithms are the essential computation tools to tailor the atomic-scale structures, chemical compositions and microstructures of materials for desired mechanical properties such as high-strength, high-toughness, high thermal and ionic conductivity, high irradiation and corrosion resistance. Via manipulating the atomic-scale dislocation, phase transformation, diffusion, and soft vibrational modes the material behaviour on plasticity, fracture, thermal, and mass transport at the macroscopic level can be predicted and optimized accurately. Therefore the framework of a predictive simulation-based optimization of advanced materials, which yet to be realized, represents a central challenge within material simulation technology. Consequently material design innovation is facing the ever-growing
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