Abstract
Large-scale molecular dynamics (MD) simulations have been performed to investigate the tensile properties and the related atomistic deformation mechanisms of the gradient nano-grained (GNG) structure of bcc Fe (gradient grains with d from 25 nm to 105 nm), and comparisons were made with the uniform nano-grained (NG) structure of bcc Fe (grains with d = 25 nm). The grain size gradient in the nano-scale converts the applied uniaxial stress to multi-axial stresses and promotes the dislocation behaviors in the GNG structure, which results in extra hardening and flow strength. Thus, the GNG structure shows slightly higher flow stress at the early plastic deformation stage when compared to the uniform NG structure (even with smaller grain size). In the GNG structure, the dominant deformation mechanisms are closely related to the grain sizes. For grains with d = 25 nm, the deformation mechanisms are dominated by GB migration, grain rotation and grain coalescence although a few dislocations are observed. For grains with d = 54 nm, dislocation nucleation, propagation and formation of dislocation wall near GBs are observed. Moreover, formation of dislocation wall and dislocation pile-up near GBs are observed for grains with d = 105 nm, which is the first observation by MD simulations to our best knowledge. The strain compatibility among different layers with various grain sizes in the GNG structure should promote the dislocation behaviors and the flow stress of the whole structure, and the present results should provide insights to design the microstructures for developing strong-and-ductile metals.
Highlights
Nano-grained (NG) metals usually have ultra-high strength, but show reduced strain hardening rate and limited ductility compared to their coarse grained (CG) counterparts, due to the incapability of effectively accumulating dislocations inside the nano-grains.[1,2,3] The structural applications in modern industry always demand stronger and tougher metals and alloys
Formation of dislocation wall and dislocation pile-up near grain boundaries (GBs) are observed for grains with d = 105 nm, which is the first observation by molecular dynamics (MD) simulations to our best knowledge
In the gradient nano-grained (GNG)/CG sandwich samples produced by the surface mechanical attrition treatment (SMAT) or the surface mechanical grinding treatment (SMGT),[11,12,13,14] the gradient layer generally has gradient grain sizes along the depth from several tens of nm to several tens of μm
Summary
Nano-grained (NG) metals usually have ultra-high strength, but show reduced strain hardening rate and limited ductility compared to their coarse grained (CG) counterparts, due to the incapability of effectively accumulating dislocations inside the nano-grains.[1,2,3] The structural applications in modern industry always demand stronger and tougher metals and alloys Such expectations have been realized by several strategies developed recently through tailoring nano-scale microstructures, such as, pre-existing growth nano-twins, nano-precipitates, bimodal grain size distribution, and gradient nano-grained (GNG) structure.[4,5,6,7,8,9,10,11,12,13,14,15,16]. Large-scale MD simulations were utilized in this work to investigate and compare the tensile properties and the related atomistic deformation mechanisms of two microstructures, i.e., the GNG structure of bcc Fe and the uniform NG structure of bcc Fe
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