Project Details
Thermomechanical properties and microstructure of fcc and bcc high-entropy alloys
Applicants
Professor Dr. Karsten Albe; Professor Dr.-Ing. Karsten Durst; Professor Dr.-Ing. Gerhard Wilde
Subject Area
Mechanical Properties of Metallic Materials and their Microstructural Origins
Term
since 2017
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 388675407
The goal of this collaborative proposal is to study the influence of lattice structure and microstructure on the thermomechanical properties of the single phase fcc Cantor (CoCrFeMnNi) and bcc Senkov (HfNbTaTiZr) alloy families in a concerted approach including experiment, theory and simulation. Our unique approach is thereby based on these stable fcc and bcc lattices and a continuous exploration of the chemical parameter space in between these model alloys as well as in the direction of subset compositions, thus contributing to the understanding of HEAs in general. We want to focus on transitions in the properties going from a diluted solid solution to a concentrated high entropy alloys, where conventional rules of mixtures, like Vegards law do not apply. For the bcc alloys we will apply experimental approaches like chemical diffusion and tracer diffusion on the HfNbTaTiZr (Senkov) and related system and analyze the phase stability as well as the solid solution strengthening and interdiffusion coefficients.For the fcc systems, we will focus on Ni-CoCrFeMnNi, Al-CoCrFeNi, as well as the Cr-CoCrFeMnNi mixed systems studying the role of grain boundaries in these fcc HEAs. In HEAs, the specific contribution of grain boundaries with respect to diffusion, segregation, phase separation and mechanical properties are mostly unknown. Processing of the fcc-alloys will involve severe plastic deformation (SPD) of the alloys with subsequent heat treatment and thermal analysis. The nanostructured HEAs after SPD are ideally suited to study phase stability, interdiffusion processes as well as the dislocation grain boundary interaction. At intermediate temperatures, grain boundaries are expected to act as nucleation centers for phase decomposition or structural phase formation. Thus, grain boundary investigations can be utilized as a looking glass for analyzing the early stages of structural instabilities in HEAs. Tracer diffusion will present an important tool for analyzing the atomic mobilities in the bulk HEAs (mainly bcc system) but also specifically along the grain boundaries (fcc systems). Microstructure investigations on all relevant length scales from the atomic (TEM) to the micron-scale (high resolution EBSD) shall reveal defect structures, lattice strain and the characteristics of internal homo- (grain boundaries) and hetero-phase interfaces such as segregation, dislocation pile-ups or strain fields. The alloys will be analyzed with respect to their mechanical properties, using macroscopic compression and nanoindentation testing from RT up to 1100°C at various strain rates. The experimental studies are closely interlinked to atomistic modelling, which provides additional insight into the lattice stability, basic deformation mechanism, diffusion mechanisms, defect structures, and particularly defect formation and defect interactions in HEAs.
DFG Programme
Priority Programmes
Co-Investigators
Dr.-Ing. Enrico Bruder; Dr. Harald Rösner; Dr. Alexander Stukowski