Cel The design of advanced high strength and damage tolerant metallic materials for energy, mobility, and health applications forms the engineering and manufacturing backbone of Europe's industry. Examples are creep-resistant Ni-alloys in power plants and plane turbines; ultrahigh strength steels, Al- and Mg-alloys for light-weight mobility and aerospace design; or Ti-implants in aging societies.Since the Bronze Age the design of metallic alloys rooted in trial and error, owing to the complexity of the physical and chemical mechanisms involved and the engineering conditions imposed during manufacturing. This traditional approach has two shortcomings. First, current alloys are not developed via systematic design rules but via empirical methods. This approach is time consuming and inefficient. Second, the increase in strength via traditional hardening mechanisms always causes a dramatic decrease in ductility, i.e. making the material brittle and susceptible to failure.SMARTMET aims at solving this inverse strength-ductility problem: The joint use of advanced synthesis and atomic characterization (expertise of PI) together with ab initio modeling (expertise of Co-PI) opens a new path to the design of next generation metallic alloys. The objective is to use these methods to identify and utilize strengthening mechanisms that allow to overcome the inverse relationship between strength and ductility. The key idea is to incorporate phases into alloys that are close or beyond their mechanical and thermodynamic stability limit. They undergo transformations under load acting as self-organized repair mechanism. SMARTMET contains risks and gains: (i) Mechanical stability through unstable phases includes the risk of material weakening but it may break the inverse strength-ductility principle. (ii) New metallurgical alloys (PI) designed via quantum mechanics (Co-PI) is risky owing to the complexity of metallic nanostructures but allows alloy tailoring based on first principles. Dziedzina nauki natural sciencesphysical sciencesquantum physics Program(-y) FP7-IDEAS-ERC - Specific programme: "Ideas" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013) Temat(-y) ERC-AG-PE5 - ERC Advanced Grant - Materials and Synthesis Zaproszenie do składania wniosków ERC-2011-ADG_20110209 Zobacz inne projekty w ramach tego zaproszenia System finansowania ERC-AG - ERC Advanced Grant Instytucja przyjmująca MAX PLANCK INSTITUT FUR EISENFORSCHUNG GMBH Wkład UE € 2 920 000,00 Adres MAX PLANCK STRASSE 1 40237 Dusseldorf Niemcy Zobacz na mapie Region Nordrhein-Westfalen Düsseldorf Düsseldorf, Kreisfreie Stadt Rodzaj działalności Research Organisations Kontakt administracyjny Birgit Neumann (Ms.) Kierownik naukowy Dierk Rolf Raabe (Dr.) Linki Kontakt z organizacją Opens in new window Strona internetowa Opens in new window Koszt całkowity Brak danych Beneficjenci (1) Sortuj alfabetycznie Sortuj według wkładu UE Rozwiń wszystko Zwiń wszystko MAX PLANCK INSTITUT FUR EISENFORSCHUNG GMBH Niemcy Wkład UE € 2 920 000,00 Adres MAX PLANCK STRASSE 1 40237 Dusseldorf Zobacz na mapie Region Nordrhein-Westfalen Düsseldorf Düsseldorf, Kreisfreie Stadt Rodzaj działalności Research Organisations Kontakt administracyjny Birgit Neumann (Ms.) Kierownik naukowy Dierk Rolf Raabe (Dr.) Linki Kontakt z organizacją Opens in new window Strona internetowa Opens in new window Koszt całkowity Brak danych
