Unraveling deformation mechanisms around FCC and BCC nanocontacts through slip trace and pileup topography analyses

Varillas, Javier; Očenášek, Jan; Torner, Jordi; Alcalá, Jorge

doi:10.1016/j.actamat.2016.11.067

Cited by 34 publications

(24 citation statements)

References 41 publications

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“…Here, the lattice constant misfit ( ε ) is defined as the difference of lattice constant between substrate and film materials: ε = ( a substrate − a film )/ a substrate , where a is the lattice constant. The films with a low ε can keep a similar growth orientation of the substrate whereas the films with a large ε prefer to grow on the plane with a minimum surface energy, such as the (111) plane in fcc film, the (110) plane in bcc films, and the (011) plane in Ti and Co films with hcp structure . The simulated films grow in two main modes, namely the Volmer–Weber mode and the Frank–van der Merwe mode resulting from the different diffusion and mobility of various atoms.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 1 shows different motion mechanisms of deposited atoms. [25][26][27] The simulated films grow in two main modes, namely the Volmer-Weber mode and the Frank-van der Merwe mode resulting from the different diffusion and mobility of various atoms. This indicates that resputtering and diffusion are two major motion mechanisms after an atom impingement.…”

Section: The Formation Of Interface and Filmmentioning

confidence: 99%

“…The intrinsic residual stress in the substrate is dependent on the interfacial profile and this stress increases as the interface are rougher. [26,37,38] This nominal stress refers to the interfacial residual stress for the deposition formed film. The stress distribution of the substrate atoms is shown in Figure 8.…”

Section: Substratementioning

confidence: 99%

See 2 more Smart Citations

Evolution of Interfacial Structure and Stress Induced by Interfacial Lattice Mismatch in Layered Metallic Nanocomposites

Hao

Lau

2018

Advcd Theory and Sims

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The interfacial structure directly affects the intrinsic residual stress caused by the interfacial lattice mismatch in layered metallic composites. This stress plays a dominant role in the mechanical, optical, magnetic, and thermal properties of nanocomposites. Here, the interfacial structure evolution and atomistic origin of intrinsic residual stress are figured out through the in situ characterization of atom arrangement and rearrangement in layered metallic nanocomposites with different interfacial misfit by using an atomistic approach. It is found that with the increment of the interfacial misfit, the interface roughens while the intrinsic residual stress increases and then reduces. The film structure dominates the evolution of interfacial structure and intrinsic residual stress when the interfacial misfit is low, whereas the effect of substrate structure on the interface and the stress is as important as the film structure with the increase of the interfacial misfit. The work demonstrates how the film structures affect the interfacial structure and intrinsic stress in layered metallic nanocomposites. Both the film and substrate structures should be taken into consideration to design layered composites with excellent properties.

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Section: Resultsmentioning

confidence: 99%

Section: The Formation Of Interface and Filmmentioning

confidence: 99%

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Evolution of Interfacial Structure and Stress Induced by Interfacial Lattice Mismatch in Layered Metallic Nanocomposites

Hao

Lau

2018

Advcd Theory and Sims

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“…Begau et al [35,36] and Stukowski and Arsenlis [37] also observed the prismatic dislocation loops in their MD simulations. The MD simulations of Varillas et al [38] studied the dislocation interaction, including prismatic loop formation, and identified the formation mechanisms of slip-step and pile-ups in FCC and BCC metals. However, these prismatic loops are not observed by conventional experiments, which have a slow indentation velocity [9,32,[39][40][41].…”

Section: Introductionmentioning

confidence: 99%

Insight into indentation-induced plastic flow in austenitic stainless steel

2020

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The indentation-induced plasticity and roughness have been investigated intensively by experiments and simulations during the last decades. However, the precise mechanisms of how dislocation flow leads to pileup formation are still not completely understood, although this is one of the initial steps causing surface roughening in tribological contacts at low loads. In this work, f001g-, f101gand f111g-grain orientations in an austenite stainless steel [(face-centered cubic (FCC) phase]) are indented with varying load forces. By using scanning electron-based methods and slip plane analysis, we reveal: (1) how slip-steps show the change of pileup formation, (2) how the slip-plane inclination determines the dislocation flow and (3) how slip-plane interactions result in the final pileup shape during indentation. We find that the flow direction transforms from the forward flow to the sideway at a transition angle of 55 À58 between the slip-plane and the surface. We use large displacement finite element method simulations to validate an inversion of the resolved shear stress at this transition angle. We provide insights into the evolution of plasticity in dislocation-mediated FCC metal indentations, with the potential application of this information for indentation simulations and for understanding the initial stage of scratching during tribology in the future.

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“…Metallic thin film coatings have attracted considerable attention due to their unique physical, mechanical and thermal properties [ 1 , 2 , 3 ], such as high strength, high hardness and high melting point, etc. Due to these excellent properties, metallic thin film coatings have been widely used in modern industry.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Interaction between Dislocation Loop and Coherent Twin Boundary in BCC Ta Film during Nanoindentation

et al. 2017

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In this work, the interaction between dislocation loop (DL) and coherent twin boundary (CTB) in a body-centered cubic (BCC) tantalum (Ta) film during nanoindentation was investigated with molecular dynamics (MD) simulation. The formation and propagation of <111> full DLs in the nanotwinned (nt) Ta film during the indentation was observed, and it was found that CTB can strongly affect the stress distribution in the Ta film, and thus change the motion and type of dislocations. There are three kinds of mechanisms for the interaction between DL and CTB in a twinned BCC Ta film: (i) dislocation absorption, (ii) dislocation desorption, and (iii) direct slip transmission. The nucleation of twin boundary dislocations and the formation of the steps in CTB were also observed during the indentation. The mechanisms presented in this work can provide atomic images for understanding the plastic deformation of BCC metals with mirror-symmetry grain boundary structures, and provide available information for the evaluation and design of high-performance nt BCC metallic thin film coatings.

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Unraveling deformation mechanisms around FCC and BCC nanocontacts through slip trace and pileup topography analyses

Cited by 34 publications

References 41 publications

Evolution of Interfacial Structure and Stress Induced by Interfacial Lattice Mismatch in Layered Metallic Nanocomposites

Evolution of Interfacial Structure and Stress Induced by Interfacial Lattice Mismatch in Layered Metallic Nanocomposites

Insight into indentation-induced plastic flow in austenitic stainless steel

Investigation of Interaction between Dislocation Loop and Coherent Twin Boundary in BCC Ta Film during Nanoindentation

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