Five-fold symmetry as indicator of dynamic arrest in metallic glass-forming liquids

Hu, Yongbin; Li, F. X.; Li, M. Z.; Bai, H. Y.; Wang, W. H.

doi:10.1038/ncomms9310

Cited by 225 publications

(118 citation statements)

References 59 publications

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“…Examples include a structural signature of dynamical slowdown as well as the liquid fragility in metallic glass-forming liquids, [26][27][28][29][30][31][32] anomalous thermal contraction of metallic melts in the nearest-neighbor shell, [33][34][35] possible crystallike order in MGs/liquids, [36][37][38][39] a fractal structure model of MGs, [40][41][42] advanced algorithms (such as machine learning methods) to efficiently characterize the structural basis of flow defects and dynamical slowdown in amorphous materials, 43,44 and a new structure parameter that incorporates dynamic (atomic vibration) information beyond the description of static structure/ configuration. [45][46][47][48][49] Computational research has played a key role in formulating these ideas.…”

Section: Introductionmentioning

confidence: 99%

“…3c) ii) Degree of five-fold local symmetry: Closely related to (i) above is the structural parameter W, defined as the average degree of fivefold local symmetry for the coordination polyhedra at the short-range scale. 27 In this approach, instead of tracking a characteristic SRO around certain species in an alloy, Hu et al 27 track the population of all the fivefold bonds in the alloy such that the metric can be applied to any alloy composition, including those for which icosahedral SRO is not preferable and those where obviously dominant SRO motifs have not been identified. Of course, this approach is expected to yield the same trend as the SRO parameter in (i) above, because any preferable SRO (motif) would be rich in local fivefold topology (the third digit of the Voronoi index is maximized for the coordination number in question).…”

Section: Introductionmentioning

confidence: 99%

“…27 iii) First peak height in the structure factor, S(q): Mauro et al 28,29 have studied the temperature dependence of the height of the first peak in S(q), as a measure of local structural order developed. This maximum peak intensity evolves with undercooling.…”

Section: Introductionmentioning

confidence: 99%

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Computational modeling sheds light on structural evolution in metallic glasses and supercooled liquids

Ding

2017

npj Comput Mater

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This article presents an overview of three challenging issues that are currently being debated in the community researching on the evolution of amorphous structures in metallic glasses and their parent supercooled liquids. Our emphasis is on the valuable insights acquired in recent computational analyses that have supplemented experimental investigations. The first idea is to use the local structural order developed, and in particular its evolution during undercooling, as a signature indicator to rationalize the experimentally observed temperature-dependence of viscosity, hence suggesting a possible structural origin of liquid fragility. The second issue concerns with the claim that the average nearest-neighbor distance in metallic melts contracts rather than expands upon heating, concurrent with a reduced coordination number. This postulate is, however, based on the shift of the first peak maximum in the pair distribution function and an average bond length determined from nearest neighbors designated using a distance cutoff. These can instead be a result of increasing skewness of the broad first peak, upon thermally exacerbated asymmetric distribution of neighboring atoms activated to shorter and longer distances under the anharmonic interatomic interaction potential. The third topic deals with crystal-like peak positions in the pair distribution function of metallic glasses. These peak locations can be explained using various connection schemes of coordination polyhedra, and found to be present already in high-temperature liquids without hidden crystal order. We also present an outlook to invite more in-depth computational research to fully settle these issues in future, and to establish more robust structure-property relations in amorphous alloys.npj Computational Materials (2017) 3:9 ;

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Computational modeling sheds light on structural evolution in metallic glasses and supercooled liquids

Ding

2017

npj Comput Mater

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“…These high cooling rates produce essentially the same glassy structure. Probably the main differences are the amount of free volume (less relaxed state) 35 and the amount of icosahedral-like clusters 36 and a higher energetic state, which is more prone to present relaxation. Figure 2 displays the evolution of Total EnergyTemperature (TE-T) curves of Cu 60.0 Zr 32.5 Ti 7.5 alloy during heating-up and cooling-down steps to determine the phase transition temperatures.…”

Section: Resultsmentioning

confidence: 99%

“…The viscosities were evaluated at different temperatures higher than glass transition and were fitted using the Vogel-Fulcher-Tamman (VFT) relationship 45 . The fragility was determined by using the following expression: According to the concept proposed by Angell 46 , the liquids can be classified within the "strong" and "fragile" extremes using T g as a scaling parameter 36,47 . The fragility is a quantitative description of diverse kinetic behaviors, and it quantifies the viscosity dependence on temperature.…”

Section: Simulated Glass Forming Resultsmentioning

confidence: 99%

Study of Glass Forming on Cu60.0Zr32.5Ti7.5 Alloy by Molecular Dynamics Simulation

et al. 2017

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This paper presents the results of Molecular Dynamics (MD) simulations of Cu 60.0 Zr 32.5 Ti 7.5 alloy through the open source code LAMMPS. Amorphous samples were produced by quenching the molten metal from 2300 to 300 K. The pair distribution functions of the liquid and solid were calculated. Moreover, the atomic short-range order at 800, 700 and 300 K was obtained by using the Voronoi tesselation method. Cu-centered icosahedral clusters were the prevailing configuration. The tensile stress-strain curve showed that the material present plastic deformation, however, shear bands were not observed in the MD simulation. The evolution of viscosity in temperatures higher than its glass transition temperature was also determined. Furthermore, the fragility of the alloy at glass temperature was evaluated.

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Perspective on Structural Evolution and Relations with Thermophysical Properties of Metallic Liquids

Wang

Jiang

2017

Advanced Materials

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The relationship between the structural evolution and properties of metallic liquids is a long-standing hot issue in condensed-matter physics and materials science. Here, recent progress is reviewed in several fundamental aspects of metallic liquids, including the methods to study their atomic structures, liquid-liquid transition, physical properties, fragility, and their correlations with local structures, together with potential applications of liquid metals at room temperature. Involved with more experimentally and theoretically advanced techniques, these studies provide more in-depth understanding of the structure-property relationship of metallic liquids and promote the design of new metallic materials with superior properties.

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Five-fold symmetry as indicator of dynamic arrest in metallic glass-forming liquids

Cited by 225 publications

References 59 publications

Computational modeling sheds light on structural evolution in metallic glasses and supercooled liquids

Computational modeling sheds light on structural evolution in metallic glasses and supercooled liquids

Study of Glass Forming on Cu60.0Zr32.5Ti7.5 Alloy by Molecular Dynamics Simulation

Perspective on Structural Evolution and Relations with Thermophysical Properties of Metallic Liquids

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