Litcius/Paper detail

Investigation and Simulation of the Effects of nm-Scale γ′ Precipitates on the Recrystallization of Ni-based Superalloys

R. Buerstmayr, Felix Theska, Ernst Kozeschnik, Richard F. Webster, M. Lison-Pick, Steven R. Street, Sophie Primig

2023Metallurgical and Materials Transactions A20 citationsDOIOpen Access PDF

Abstract

Abstract Superalloys are critical materials for the hottest sections of stationary gas turbines and aircraft engines. Homogeneously fine-grained microstructures are essential to unlock their superior high-temperature strength but are challenging to achieve in γ ′-containing Ni-based superalloys. Such microstructures are achieved by recrystallization through hot working and grain boundary pinning via μ m-scale second phase particles. Discontinuous dynamic recrystallization is the predominant restoration mechanism, where grain growth is restricted by Zener pinning. Nanometer-scale γ ′ precipitates may exercise similar pinning during the nucleation stage and thus delay recrystallization. While the effects of coarse, μ m-scale, precipitates during recrystallization and grain growth are well-known, descriptions for fine coherent precipitates are currently lacking. To address this scarcity of knowledge, both γ ′-rich and -lean microstructures of the γ ′-containing Ni-base superalloy René 41 underwent identical uniaxial hot compression tests. Flow stress and microstructural analyses reveal the inhibition of recrystallization by nm-scale γ ′ precipitates during both nucleation and growth stages. This effect is successfully described using thermo-kinetic modeling through application of a driving-force based model. These unique insights provide a novel pathway to unlock homogeneously fine-grained microstructures in γ ′-containing Ni-based superalloys via advanced thermo-mechanical processing routes, required for applications in future generations of gas turbines and aircraft engines.

Topics & Concepts

SuperalloyRecrystallization (geology)Materials scienceNucleationDynamic recrystallizationMicrostructureGrain boundaryMetallurgyHot workingThermodynamicsGeologyPaleontologyPhysicsMetallurgy and Material FormingMicrostructure and mechanical propertiesHigh Temperature Alloys and Creep