Numerical Study and Experimental Validation of Deformation of &lt;111&gt; FCC CuAl Single Crystal Obtained by Additive Manufacturing

Anton Y Nikonov,Olga S Novitskaya,Lilia L Lychagina,Dmitry V Lychagin,Artem A Bibko,Andrey I Dmitriev

doi:10.3390/met11040582

Abstract

The importance of taking into account directional solidification of grains formed during 3D printing is determined by a substantial influence of their crystallographic orientation on the mechanical properties of a loaded material. This issue is studied in the present study using molecular dynamics simulations. The compression of an FCC single crystal of aluminum bronze was performed along the <111> axis. A Ni single crystal, which is characterized by higher stacking fault energy (SFE) than aluminum bronze, was also considered. It was found that the first dislocations started to move earlier in the material with lower SFE, in which the slip of two Shockley partials was observed. In the case of the material with higher SFE, the slip of a full dislocation occurred via successive splitting of its segments into partial dislocations. Regardless of the SFE value, the deformation was primarily occurred by means of the formation of dislocation complexes involved stair-rod dislocations and partial dislocations on adjacent slip planes. Hardening and softening segments of the calculated stress–strain curve were shown to correspond to the periods of hindering of dislocations at dislocation pileups and dislocation movement between them. The simulation results well agree with the experimental findings.

Highlights

Progress in additive technologies has attracted even more attention to the role of classic substructural mechanisms of deformation and hardening of metal materials
These studies are concerned with the investigation of the characteristic features of plastic deformation depending on the crystallographic orientation of a single crystal in relation to the loading direction [9,10,11,12]
The investigations revealed that the beginning of the formation of dislocation structure is determined by the energetic characteristics of the material

Summary

Introduction

Progress in additive technologies has attracted even more attention to the role of classic substructural mechanisms of deformation and hardening of metal materials. This is concerned with the directional crystallization of grains and the formation of a so-called dendritic structure in the materials produced by additive manufacturing [1,2,3,4,5]. Tang et al [7] analyzed deformation properties of individual structures composed of dendritic cores in nickel-based superalloy subjected to an industrially relevant process simulation and revealed the complex interplay between microstructural development and micromechanical behavior. These studies are concerned with the investigation of the characteristic features of plastic deformation depending on the crystallographic orientation of a single crystal in relation to the loading direction [9,10,11,12]

Objectives

Results

Conclusion