Molecular Dynamics Study on Adhesion of Various Ni/Al Interface for Ni-Plated Aluminum Alloys

Yashiro, Keiji; Nimura, Kouhei; Naito, K.

doi:10.2320/matertrans.m2018182

Cited by 5 publications

(2 citation statements)

References 15 publications

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“…Elzas and Thijsse propose a cohesive law for crack growth along Fe/precipitate interfaces [21]. In fact, spontaneous cracking along the bi-metal interface cannot be expected since the rupture occurs in either side of lower surface energy and elastic constants, as reported in our previous study on adhesion of Ni/Al interface [22]. However, some impurities such as oxide and precipitate could initiate cracking along interfaces.…”

Section: Introductionmentioning

confidence: 92%

Molecular dynamics study on atomic elastic stiffness at mode I crack along bi-metal interface

Yashiro

2021

Phil. Trans. R. Soc. A.

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Propagation of mode I crack along bi-metal (001) interfaces of Fe/W, Fe/Ni, Fe/Co and Ti/Mg is simulated by molecular dynamics and discussed with the eigenvalue/vector of the atomic elastic stiffness, B i j a = Δ σ i a / Δ ε j , and surface energy. The crack does not propagate at the interface but in the adjacent phase of smaller surface energy, except in Fe/Ni. The 1st eigenvalue η a (1) , or the solution of B i j a Δ ε j = η a Δ ε i of each atom, clarifies the difference of ‘soft/hard’ of both phases at the onset of crack propagation. In the case of Fe/Ni, the η a (1) of Ni atoms remarkably decreases in the Fe/Ni bi-metal structure, even though Ni has higher η a (1) than Fe at no-load perfect lattices. Thus the rupture occurs in the Ni side even though the Ni has slightly higher (001) surface energy than Fe. Deformation modes at the crack propagation are also visualized by the eigenvector of η a (1) < 0 unstable atoms. This article is part of the theme issue ‘Fracture dynamics of solid materials: from particles to the globe’.

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Section: Introductionmentioning

confidence: 92%

Molecular dynamics study on atomic elastic stiffness at mode I crack along bi-metal interface

Yashiro

2021

Phil. Trans. R. Soc. A.

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“…The interaction forces calculated from the MD simulations were used for finite element method (FEM) computations, so that they compared it with interfacial fracture property obtained from micro-indentation tests. Yashiro et al [21] also performed an MD simulation of Ni plating on aluminum alloys and discussed the interfacial fracture behavior of Ni coating and the effect of phosphorus on the fracture strength. In a study of fatigue loading using MD, Lei Ma et al [22] investigated the fatigue crack growth characteristics of pre-cracked single-crystal bcc iron under repeated loading with strain control.…”

Section: Introductionmentioning

confidence: 99%

Repeated Laser Shock-Wave Adhesion Test for Metallic Coatings: Adhesion Durability and Its Mechanism Studied by Molecular Dynamics Simulation

et al. 2021

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We evaluated the adhesion of polycrystalline metallic coatings using the laser shock-wave adhesion test (LaSAT). This study used Cu plating on stainless steel as a coating model. The adhesion strength and toughness were successfully estimated using LaSAT and finite element method with cohesive zone model. Next, repeated LaSAT was conducted to apply cyclic loading to evaluate adhesion fatigue life, i.e., the number of loading cycles required for delamination. Furthermore, this study performed molecular dynamics (MD) simulations to elucidate the adhesion mechanism for the Cu/Fe interface. To verify our model, the interfacial fracture toughness was computed using the MD simulation and compared with the results of LaSAT. Next, cyclic loading was applied to the MD model to investigate crack initiation around the interface. We found that dislocations are generated from the internal grain and are accumulated at grain boundaries. This accumulation results in fatigue crack initiation due to stress concentration.

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Atomistic investigation on adhesive strength of coupling agents to aluminum

Fukui

Okunishi

Hara

et al. 2023

International Journal of Mechanical Sciences

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Molecular Dynamics Study on Adhesion of Various Ni/Al Interface for Ni-Plated Aluminum Alloys

Cited by 5 publications

References 15 publications

Molecular dynamics study on atomic elastic stiffness at mode I crack along bi-metal interface

Molecular dynamics study on atomic elastic stiffness at mode I crack along bi-metal interface

Repeated Laser Shock-Wave Adhesion Test for Metallic Coatings: Adhesion Durability and Its Mechanism Studied by Molecular Dynamics Simulation

Atomistic investigation on adhesive strength of coupling agents to aluminum

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