Length scales and scale-free dynamics of dislocations in dense solid solutions

Péterffy, Gábor; Ispánovity, Péter Dusán; Foster, Michael E.; Zhou, Xiaowang; Sills, Ryan B.

doi:10.1186/s41313-020-00023-z

Cited by 16 publications

(16 citation statements)

References 56 publications

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“…It will allow to assess the influence of stress correlations on the dislocation roughness (i.e. the shape of the dislocation line) and to clarify recent results obtained with atomistic calculations [53] and continuous modeling [35]. More importantly, it will allow to investigate the solid solution strengthening in concentrated alloys by estimating the critical stress to unpin a dislocation from the underlying correlated stress.…”

Section: Stress Correlations and Dislocationsmentioning

confidence: 97%

Microelasticity model of random alloys. Part II: displacement and stress correlations

Geslin

Rida

Rodney

2021

Journal of the Mechanics and Physics of Solids

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In this two-part article, we propose elastic models of disordered alloys to study the statistical properties of the random displacement and stress fields emerging from the random distributions of atoms of different sizes. In Part I, we presented realand Fourier-space approaches enabling to obtain the amplitude of the fluctuations through the mean square displacements and stresses. In the present Part II, we extend the Fourier approach to address spatial correlations. We show that, even if the alloy is fully disordered and elastically isotropic, correlations are highly anisotropic. Our continuum predictions are validated by comparisons with atomistic models of random alloys. We also discuss the consequence of displacement correlations on finite size effects in atomistic calculations and on diffuse X-ray and neutron scattering experiments and the possible implications of stress correlations on dislocation behavior.Random alloys are solid solutions of two or more components where atoms of different nature are located randomly on the crystalline lattice. The plasticity of random alloys has been of significant interest for several decades [1, 2, 3] but has recently attracted a renewed attention with the development of high entropy alloys (HEA) [4,5,6]. The size difference between the alloy components induces displacements of the atoms from their lattice sites, as well as internal stresses. These atomic displacements, also referred to as "lattice distortion" in the literature [5,6] have been the focus of multiple studies because they were found to correlate well with solid solution strengthening and can be assessed by both experimental (using X-ray [5

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Section: Stress Correlations and Dislocationsmentioning

confidence: 97%

Microelasticity model of random alloys. Part II: displacement and stress correlations

Geslin

Rida

Rodney

2021

Journal of the Mechanics and Physics of Solids

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“…Traditional elastic depinning theory [9,10] has been long thought to be the core basis of the description of the behavior of single dislocations in general disordered environments [10][11][12], and more specifically in solid solutions [13,14] where chemical disorder proliferates. The key prediction of such elastic depinning theories is the onset of a characteristic length scale, the dislocation correlation length ξ, below which the dislocation line displays fractal characteristics with non-trivial roughness.…”

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confidence: 99%

“…The choices of the studied materials are motivated by prior studies that provided benchmarks for traditional depinning behavior (Fe 0.7 Ni 0.11 Cr 0.19 [13], FeNi [14]), and also by motivating experimental findings on equiatomic multicomponent alloys (CrCoNi, CrMnCoNi, CrFeCoNi, CrMnFeCoNi, Fe 0.4 Mn 0.27 Ni 0.26 Co 0.05 Cr 0.02 ) that point towards exceptional strength [17][18][19][20][21]. Equiatomic fcc HEAs with low stacking fault energy showed an excellent balance between strength and ductility, particularly at cryogenic temperatures [3,4].…”

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confidence: 99%

“…Our focus is the depinning behavior of a model configuration of single edge dislocations under shear stress that drive ideal dislocation glide at the low temperature of 5K. MD simulations can successfully describe the complicated interaction between stacking faults and chemical disorder during loading, at the atomic scale [13,14]. There are several MD based studies that explained the core structure of dislocations as well as the interaction of dislocations with solutes in fcc traditional alloys [13,14,24].…”

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confidence: 99%

“…MD simulations can successfully describe the complicated interaction between stacking faults and chemical disorder during loading, at the atomic scale [13,14]. There are several MD based studies that explained the core structure of dislocations as well as the interaction of dislocations with solutes in fcc traditional alloys [13,14,24]. Consistently with these prior studies, our simulations are characterized by a simulation cell with fcc crystal and random distribution of constituent elements, created along X = [110](l x = 252 Å), Y = [ 111](l y = 122 Å), and Z = [1 12](l z = 2002 Å) containing 5,432,700 atoms (see Fig.…”

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confidence: 99%

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Edge dislocations in multi-component solid solution alloys: Beyond traditional elastic depinning

Esfandiarpour¹,

Papanikolaou²,

Alava³

2021

Preprint

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High-entropy alloys (HEA) form solid solutions with large chemical disorder and excellent mechanical properties. We investigate the origin of HEA strengthening in face-centered cubic (FCC) singlephase HEAs through molecular dynamics simulations of dislocations, in particular, the equiatomic CrCoNi, CrMnCoNi, CrFeCoNi, CrMnFeCoNi, FeNi, and also, Fe0.4Mn0.27Ni0.26Co0.05Cr0.02, Fe0.7Ni0.11Cr0.19. The dislocation correlation length ξ, roughness amplitude Ra, and stacking fault widths WSF are tracked as a function of stress. All alloys are characterized by a well defined depinning stress (σc) and we find a novel regime where exceptional strength is observed, and a fortuitous combination takes place, of small stacking fault widths and large dislocation roughness Ra. Thus the depinning of two partials seems analogous to unconventional domain wall depinning in disordered magnetic thin films. This novel regime is identified in specific compositions commonly associated with exceptional mechanical properties (CrCoNi, CrMnCoNi, CrFeCoNi, and CrMnFeCoNi). Yield stress from analytical solute-strengthening models underestimates largely the results in these cases. A possible strategy for increasing strength in multi-component single-phase alloys is the combined design of stacking fault width and element-based chemical disorder.

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Statistical Modeling of the Orowan Bypass Mechanism for Randomly Distributed Obstacles

Szajewski

Crone

Knap

2023

Metall Mater Trans A

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Length scales and scale-free dynamics of dislocations in dense solid solutions

Cited by 16 publications

References 56 publications

Microelasticity model of random alloys. Part II: displacement and stress correlations

Microelasticity model of random alloys. Part II: displacement and stress correlations

Edge dislocations in multi-component solid solution alloys: Beyond traditional elastic depinning

Statistical Modeling of the Orowan Bypass Mechanism for Randomly Distributed Obstacles

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