Abstract
Single-crystal Ni-base superalloys, consisting of a two-phase γ/ microstructure, retain high strengths at elevated temperatures and are key materials for high temperature applications, like, e.g., turbine blades of aircraft engines. The lattice misfit between the γ and phases results in internal stresses, which significantly influence the deformation and creep behavior of the material. Large-scale atomistic simulations that are often used to enhance our understanding of the deformation mechanisms in such materials must accurately account for such misfit stresses. In this work, we compare the internal stresses in both idealized and experimentally-informed, i.e., more realistic, γ/ microstructures. The idealized samples are generated by assuming, as is frequently done, a periodic arrangement of cube-shaped particles with planar γ/ interfaces. The experimentally-informed samples are generated from two different sources to produce three different samples—the scanning electron microscopy micrograph-informed quasi-2D atomistic sample and atom probe tomography-informed stoichiometric and non-stoichiometric atomistic samples. Additionally, we compare the stress state of an idealized embedded cube microstructure with finite element simulations incorporating 3D periodic boundary conditions. Subsequently, we study the influence of the resulting stress state on the evolution of dislocation loops in the different samples. The results show that the stresses in the atomistic and finite element simulations are almost identical. Furthermore, quasi-2D boundary conditions lead to a significantly different stress state and, consequently, different evolution of the dislocation loop, when compared to samples with fully 3D boundary conditions.
Highlights
Ni-base superalloys are an excellent class of high-temperature materials that are used as single-crystal turbine blades in aircraft engines and power plants [1]
Scub is shifted periodically so that the channels are in the center of the picture; (d) Atomistic sample S2Dp ; (e) Atomistic sample S2DSEM obtained by digitizing scanning electron microscope (SEM) micrograph; (f) atom probe tomography (APT)-informed atomistic sample S APT,stoi with stoichiometric chemical composition; (g) APT-informed atomistic sample S APT,non−stoi with non-stoichiometric chemical composition
We investigate the distribution of eigenstresses as obtained from atomistic simulations of different samples with γ/γ0 microstructures; the eigenstresses here being a direct consequence of the lattice misfit between the two phases
Summary
Ni-base superalloys are an excellent class of high-temperature materials that are used as single-crystal turbine blades in aircraft engines and power plants [1]. Comprised of a two-phase γ/γ0 microstructure, these single crystals exhibit the ability to withstand high thermo-mechanical loads at temperatures well above 1200 K. The lattice misfit between the γ and γ0 phases results in internal stresses in the microstructure. These misfit stresses have a significant influence on the mechanical and high temperature creep behavior of the material. Misfit stresses are known to influence the evolution of the shape of the precipitates at elevated temperatures [4]. It is evident that the incorporation of the appropriate misfit stress state is paramount towards modeling the mechanical behavior of γ/γ0 microstructures
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