Uniaxial tension deformation study of copper/nickel laminated composites: Effects of lamella number and interlamellar spacing

[Display omitted] •MD simulations on uniaxial tension of Cu/Ni NLCs.•Effects of lamella number and interlamellar spacing on mechanical properties.•Ni reinforcement & semi-coherent interface obstruction on dislocation motions.•Opposite change trends of total dislocation length and flow stress. Th...

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Bibliographic Details
Published in:Computational materials science 2020-01, Vol.171, p.109272, Article 109272
Main Authors: Wang, Yang, Zuo, Jie, Jiang, Naisheng, Niu, Kangmin, Wu, Ying
Format: Article
Language:English
Subjects:
Cu/Ni nano-laminated composite
Dislocation
Molecular dynamics
Uniaxial tension
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Summary:[Display omitted] •MD simulations on uniaxial tension of Cu/Ni NLCs.•Effects of lamella number and interlamellar spacing on mechanical properties.•Ni reinforcement & semi-coherent interface obstruction on dislocation motions.•Opposite change trends of total dislocation length and flow stress. The lamella number and interlamellar spacing are crucial structural parameters in determining mechanical properties of layered nanocomposites, while they are rarely discussed. Herein, we investigate effects of the two parameters on mechanical properties of copper/nickel (Cu/Ni) nano-laminated composites (NLCs) under uniaxial tension using molecular dynamic simulation. The Cu/Ni NLCs with one single Ni laminate exhibit the largest enhancement in Young’s modulus (E = 121 GPa) and yield strength (σz = 9.8 GPa), attributing to the stronger texture of Ni and interfacial blocking effect on the motion of dislocations. With different Ni layer spacing, the shockley dislocations form a crescent slip plane and enter the Cu matrices along the 45° direction with respect to the Ni laminate. According to the evolution of dislocation length, the flow stress shows a negative relationship with the mean dislocation length. The peak yield strength coincides with the stage of sudden increase of the total dislocation length, indicating decreased mechanical properties with increased dislocation length. These findings provide fundamental relationships between nanoscale laminated structure and macroscopic mechanical properties of Cu/Ni composites, shedding new lights on the rational design of NLCs with enhanced mechanical performances.
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2019.109272