Anisotropic structural predictor in glassy materials

Schwartzman-Nowik, Zohar; Lerner, Edan; Bouchbinder, Eran

doi:10.1103/physreve.99.060601

Cited by 35 publications

(31 citation statements)

References 30 publications

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“…One is the increased internal data noise of the STZ data, if the data is collected from a single loading condition. As discussed in the Introduction, stress-activated plastic heterogeneity is quite sensitive to the loading conditions such as loading mode and direction 25,26 ; thus, if using data from a single loading condition, non-trivial noise could be introduced in the collected data. For the thermal activation data, as used in this work, the absence of nonuniform stress eliminates the loading-related noises, and probing sufficient elementary ART events can guarantee a well-converged E act to indicate the susceptibility to thermal excitation.…”

Section: Transferability To Identifying Shear Transformation Propensitymentioning

confidence: 99%

“…However, the accuracy achieved in these attempts is not yet sufficiently high, and the reported scoring metric, e.g., recall or area under the receiver operating characteristic curve (AUC-ROC), is typically below 80%. One reason for this is that the elementary excitations upon shear transformations are complicated by the non-uniform tensorial stress field in the solid under deformation, as well as the dependence of activation on loading conditions (e.g., loading mode and direction) 25,26 . If not properly dealt with, these would introduce non-trivial noises in the accrued data and influence adversely the quality of the learnt structure-property relations.…”

Section: Introductionmentioning

confidence: 99%

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Predicting the propensity for thermally activated β events in metallic glasses via interpretable machine learning

et al. 2020

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The elementary excitations in metallic glasses (MGs), i.e., β processes that involve hopping between nearby sub-basins, underlie many unusual properties of the amorphous alloys. A high-efficacy prediction of the propensity for those activated processes from solely the atomic positions, however, has remained a daunting challenge. Recently, employing well-designed site environment descriptors and machine learning (ML), notable progress has been made in predicting the propensity for stress-activated β processes (i.e., shear transformations) from the static structure. However, the complex tensorial stress field and direction-dependent activation could induce non-trivial noises in the data, limiting the accuracy of the structure-property mapping learned. Here, we focus on the thermally activated elementary excitations and generate high-quality data in several Cu-Zr MGs, allowing quantitative mapping of the potential energy landscape. After fingerprinting the atomic environment with short- and medium-range interstice distribution, ML can identify the atoms with strong resistance or high compliance to thermal activation, at a high accuracy over ML models for stress-driven activation events. Interestingly, a quantitative “between-task” transferring test reveals that our learnt model can also generalize to predict the propensity of shear transformation. Our dataset is potentially useful for benchmarking future ML models on structure-property relationships in MGs.

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Section: Transferability To Identifying Shear Transformation Propensitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Predicting the propensity for thermally activated β events in metallic glasses via interpretable machine learning

et al. 2020

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“…At larger strains, however, the response becomes nonlinear and intermittent. In the meanfield description, the Gardner transition gives rise to this behavior, but in finite dimensions both collective and local excitations likely contribute [112][113][114][115][116][117][118][119][120][121][122] . The glass then either yields or jams, as illustrated in the phase diagram of Fig.…”

Section: A Stress-strain Curvesmentioning

confidence: 99%

“…Recent extension of the theory to the thermal regime using soft harmonic spheres 90,91 will likely be followed by numerical work in finite dimension. An exciting possibility would be for these studies to provide a sharper understanding of the rheological role of localized excitations [112][113][114][115][116][117][118][119][120][121][122] , as a counterpart of the comparable excitations observed in isotropically cooled or compressed systems.…”

Section: Nonlinear Responsementioning

confidence: 99%

Gardner physics in amorphous solids and beyond

Berthier

Biroli

Charbonneau

et al. 2019

The Journal of Chemical Physics

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One of the most remarkable predictions to emerge out of the exact infinite-dimensional solution of the glass problem is the Gardner transition. Although this transition was first theoretically proposed a generation ago for certain mean-field spin glass models, its materials relevance was only realized when a systematic effort to relate glass formation and jamming was undertaken. A number of nontrivial physical signatures associated to the Gardner transition have since been considered in various areas, from models of structural glasses to constraint satisfaction problems. This Perspective surveys these recent advances and discusses the novel research opportunities that arise from them. a arXiv:1902.10494v2 [cond-mat.stat-mech]

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“…It is precisely this population of soft QLMs, and their interaction with phonons, that is thought to influence various unexplained universal phenomena that are specific to structural glasses [20][21][22]26]. Furthermore, a subset of QLMs were shown to represent the carriers of plasticity in externally-loaded glasses [30,31,39], and might be key in determining relaxation patterns in supercooled liquids [32][33][34]. Therefore, knowledge of their full distribution is crucial for advancing our fundamental understanding of many glassy phenomena.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear quasilocalized excitations in glasses: True representatives of soft spots

2020

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Structural glasses formed by quenching a melt possess a population of soft quasilocalized excitations -often called 'soft spots' -that are believed to play a key role in various thermodynamic, transport and mechanical phenomena. Under a narrow set of circumstances, quasilocalized excitations assume the form of vibrational (normal) modes, that are readily obtained by a harmonic analysis of the multi-dimensional potential energy. In general, however, direct access to the population of quasilocalized modes via harmonic analysis is hindered by hybridizations with other low-energy excitations, e.g. phonons. In this series of papers we re-introduce and investigate the statistical-mechanical properties of a class of low-energy quasilocalized modes -coined here nonlinear quasilocalized excitations (NQEs) -that are defined via an anharmonic (nonlinear) analysis of the potential energy landscape of a glass, and do not hybridize with other low-energy excitations. In this first paper, we review the theoretical framework that embeds a micromechanical definition of NQEs. We demonstrate how harmonic quasilocalized modes hybridize with other soft excitations, whereas NQEs properly represent soft spots without hybridization. We show that NQEs' energies converge to the energies of the softest, non-hybridized harmonic quasilocalized modes, cementing their status as true representatives of soft spots in structural glasses. Finally, we perform a statistical analysis of the mechanical properties of NQEs, which results in a prediction for the distribution of potential energy barriers that surround typical inherent states of structural glasses, as well as a prediction for the distribution of local strain thresholds to plastic instability. arXiv:1912.10930v1 [cond-mat.soft]

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Anisotropic structural predictor in glassy materials

Cited by 35 publications

References 30 publications

Predicting the propensity for thermally activated β events in metallic glasses via interpretable machine learning

Predicting the propensity for thermally activated β events in metallic glasses via interpretable machine learning

Gardner physics in amorphous solids and beyond

Nonlinear quasilocalized excitations in glasses: True representatives of soft spots

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