Quantifying the High-Temperature Separation Behavior of Lamellar Interfaces in γ-Titanium Aluminide Under Tensile Loading by Molecular Dynamics

Abstract: γ-titanium aluminide (TiAl) alloys with fully lamellar microstructure possess excellent properties for high-temperature applications. Such fully lamellar microstructure has interfaces at different length scales. The separation behavior of the lamellae at these interfaces is crucial for the mechanical properties of the whole material. Unfortunately, quantifying it by experiments is difficult. Therefore, we use molecular dynamics (MD) simulations to this end. Specifically, we study the high-temperature separatio… Show more

“…At present, the results obtained by simulation can describe the evolutions of materials microstructures and mechanical properties suitably at spatial-temporal scale in order to find the constitutive relations of universality [6,7]. Many academic studied the nucleation and propagation of the dislocation during tensile process by molecular dynamics, and the dislocation is easily nucleated at the grain boundary and the secondary phase due to the influence of stress with the degree of deformation increasing [8,9]. At the same time, academics studied that the strength of materials exhibited a trend of first decreasing and then increasing in the grain of Al and Cu due to work hardening with the density of dislocation increasing [10].…”

Molecular dynamics simulations of tensile mechanical properties and microstructures of Al-4.5Cu alloy: the role of temperature and strain rate

“…At present, the results obtained by simulation can describe the evolutions of materials microstructures and mechanical properties suitably at spatial-temporal scale in order to find the constitutive relations of universality [6,7]. Many academic studied the nucleation and propagation of the dislocation during tensile process by molecular dynamics, and the dislocation is easily nucleated at the grain boundary and the secondary phase due to the influence of stress with the degree of deformation increasing [8,9]. At the same time, academics studied that the strength of materials exhibited a trend of first decreasing and then increasing in the grain of Al and Cu due to work hardening with the density of dislocation increasing [10].…”

Molecular dynamics simulations of tensile mechanical properties and microstructures of Al-4.5Cu alloy: the role of temperature and strain rate

A Study of Compression Deformation Behavior of γ/α2 Interface in γ(TiAl) Alloy Using Molecular Dynamics Simulation

Investigating the microplastic behavior of hierarchical polycrystalline γ-TiAl microstructures