Part 1: Introduction and Basics 1. Introduction, success in bridging and specific problems 2. Past, present and future of SX superalloys 3. Fundamentals: Thermodynamics and kinetics 4. Elastic properties, tensor properties 5. Microstructure and chemical characterization, (incl. Image Analysis) 6. Mechanical characterization 7. Elementary deformation: High temperature plasticity 8. Elementary damage process: Creep rupture, fatigue initiation, crack propagation
Part 2: Building SX parts 9. Processing (SX, DS), solidification and heat treatment 10. Ageing (microstructure evolution) 11. Refurbishment 12. Coated SX: High temperature and corrosion protection, thermal insulation
Part 3: Appropriate scale modeling, scale bridging methods 13. AM, MD, DFT atomic scale 14. DDD 15. Phase field 16. Crystal plasticity models: Dislocation based and Phenomenological approach 17. Macroscopic microstructure sensitive mechanical modeling 18. Crystal plasticity and damage at notches and crack tips in single crystal nickel-based alloys
Part 4: Application to engineering cases 19. Finite element implementation of crystal plasticity models in large deformation 20. Complex load spectra including full physical coupling and integrating advanced assessment procedures into component design (component design and life extension
Professor Loeïz Nazé is an associate professor at the Mines ParisTech in the Materials Center. His areas of expertise include metallurgy and crystallography and his current areas of research include metallurgy, microstructures, and plastic deformation. Professor Naze studied engineering at the Lille University School of Engineering.
Vincent Maurel, Ph.D. is a senior scientist with the Centre des Materiaux at the MINES Paris Tech. His areas of research include fatigue of materials at high temperature, mono and poly-crystalline superalloys, and analysis of coatings for turbine blades.
Gunther Eggeler is Chair of the Materials Science and Engineering at Ruht-Universitate Bochum. Since 2012 he is director of the collaborative research centre SFB/Transregio 103 - From Atoms to Turbine Blades - Scientific Basis for a new Generation of Single Crystal Super Alloys. From 2000 to 2011 he served as director of the collaborative research centre SFB 459 - Formgedächtnistechnik (Shape Memory Technology). He is member of the scientific advisory boards of ICOMAT (International Conference on Martensitic Transformations) and ESOMAT (European Symposium on Martensitic Transformations). He is leader of a high temperature materials research group at the Max Planck Institut für Eisenforschung (MPIE) and full member of the North Rhine Westphalian Academy of Sciences. As material scientist Gunther Eggeler studies elementary microstructural processes which govern the deformation and transformation behaviour of structural and functional engineering materials
Jonathan Cormier, Ph.D is He is an Associate Professor at ISAE-ENSMA. His current research focusses on Mechanical behavior of cast and forged Ni-based superalloys (isothermal and non-isothermal creep, fatigue, Thermo-mechanical fatigue); Damage processes and crack initiation in Ni-based alloys; Microstructure-Mechanical properties of superalloys; Constitutive modeling of the inelastic behavior of Ni-based alloys; Burner rig testing; durability of Thermal Barrier Coating systems. He currently serves as an editor of the Metallurgical and Materials Transactions A, B and E journals and was the recipient of the Jean-Rist Medal in 2015.
Georges Cailletaud is a Professor at Mines ParisTech, a position he has held since 1994. He served as Director of the CNRS research unit at Centre des Matériaux (2006-2011) and deputy Director of the Department of Mechanics and Materials at Mines ParisTech (2008-2011). His main contributions deal with material modeling at various scales, specifically plastic and viscoplastic formulations for isothermal and non-isothermal loading, with crystal plasticity applied to single crystal and polycrystalline agregates, with damage development and crack initiation models. His work includes the developments of the model themselves and of the numerical methods needed for the numerical implementation in finite element codes. He is the author of two books.