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The influence of grain boundary character distribution on the high-temperature creep behavior and damage mechanism of Inconel 718

Dongyang Hao, Qian Wang, Haikun Ma, Dayong Wu, Jie Kang, Huicong Dong, Baocai You, Ning Li, Ru Su

2024Materials & Design11 citationsDOIOpen Access PDF

Abstract

• Dissecting the impact of grain boundary characteristic distribution on creep behavior and damage mechanism of Inconel 718 superalloy. • The role of high proportion of co-lattice twin boundaries to creep was discussed. • Discontinuous dynamic recrystallisation (DDRX) and continuous dynamic recrystallisation (CDRX) mechanisms during the creep process were analyzed. • Formation of new stable grain boundaries by recrystallisation was observed. Thermomechanical processing as the main method of grain boundary engineering (GBE), can modulate the grain boundary character distribution (GBCD) in turn affects the mechanical properties and stability of alloys at high temperature. In this study, the microstructural evolution and creep behaviour of different GBCD alloys were investigated during the creep process at 660 °C and 690 MPa, and the effect of GBCD on high temperature creep behaviour and associated damage mechanism were analyzed from the viewpoints of grain size, recrystallisation and dislocation motion. The findings indicate that the larger grain size prolongs the steady-state creep duration, which is beneficial to the increase of creep life. During the creep process, the coherent twin boundary is susceptible to transformation into non-coherent twin boundary, resulting in the loss of its difficult-to-migrate properties and increased susceptibility to becoming recrystallisation nucleation sites. Furthermore, the formation of twins is conducive to the stimulation of dynamic recrystallisation. Discontinuous dynamic recrystallisation, characterised by the nucleation and growth of grains, occurs concurrently with continuous dynamic recrystallisation with strain gradients and orientations. The combined effect of these processes is grain boundary slip and restricted dislocation migration, which in turn alter the creep properties of the alloy.

Topics & Concepts

Materials scienceInconelCreepGrain boundaryMechanism (biology)MetallurgyCharacter (mathematics)Grain boundary strengtheningComposite materialMicrostructureAlloyGeometryMathematicsPhilosophyEpistemologyHigh Temperature Alloys and CreepHigh-Velocity Impact and Material BehaviorMicrostructure and mechanical properties
The influence of grain boundary character distribution on the high-temperature creep behavior and damage mechanism of Inconel 718 | Litcius