Metastable quasicrystal-induced nucleation in a bulk glass-forming liquid

Kurtuldu, Güven; Shamlaye, Karl F.; Löffler, Jörg F.

doi:10.1073/pnas.1717941115

Cited by 43 publications

(29 citation statements)

References 59 publications

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“…That is, the presence of such crystallographic defects causes the spiral growth form. While screw dislocation-driven growth has been reported in diverse areas of crystallization [37,[43][44][45][46] -and indeed extensions of the Burton-Cabrera-Frank [30] spiral growth model exist [47] our proposed mechanism on the role of "hidden" polytetrahedral phases in assisting heterogeneous nucleation supports and expands upon recent reports, [11,48] for instance, metastable quasicrystal-induced nucleation yielding grain-refined alloys, [49] among other two-step solidification pathways.…”

Section: Development Of Spiral Patterns From Nano-to Micro-scalesupporting

confidence: 74%

“…The centrality of crystallization phenomena in many scientific fields has spurred decades of research into this “secretive” process. By tuning the growth conditions, it is possible to steer the system down different kinetic pathways to produce transient or metastable states (e.g., polytetrahedral or disordered phases) on intermediate time–scales . In particular, non‐equilibrium routes to metastable states could unveil patterns not seen in equilibrium states.…”

Section: Introductionmentioning

confidence: 99%

“…By tuning the growth conditions, it is possible to steer the system down different kinetic pathways to produce transient or metastable states (e.g., polytetrahedral or disordered phases) on intermediate time-scales. [10,11] In particular, non-equilibrium routes to metastable states could unveil patterns not seen in equilibrium states. Thus, an understanding of crystallization phenomena is the key to lock into place materials with morphologies and/ or functionalities not present in equilibrium states.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Multi‐Step Crystallization of Self‐Organized Spiral Eutectics

Moniri

Bale

Volkenandt

et al. 2020

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A method for the solidification of metallic alloys involving spiral self‐organization is presented as a new strategy for producing large‐area chiral patterns with emergent structural and optical properties, with attention to the underlying mechanism and dynamics. This study reports the discovery of a new growth mode for metastable, two‐phase spiral patterns from a liquid metal. Crystallization proceeds via a non‐classical, two‐step pathway consisting of the initial formation of a polytetrahedral seed crystal, followed by ordering of two solid phases that nucleate heterogeneously on the seed and grow in a strongly coupled fashion. Crystallographic defects within the seed provide a template for spiral self‐organization. These observations demonstrate the ubiquity of defect‐mediated growth in multi‐phase materials and establish a pathway toward bottom‐up synthesis of chiral materials with an inter‐phase spacing comparable to the wavelength of infrared light. Given that liquids often possess polytetrahedral short‐range order, our results are applicable to many systems undergoing multi‐step crystallization.

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Section: Development Of Spiral Patterns From Nano-to Micro-scalesupporting

confidence: 74%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Multi‐Step Crystallization of Self‐Organized Spiral Eutectics

Moniri

Bale

Volkenandt

et al. 2020

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“…Particularly, such a method has been used to investigate unique features of active fluids-a novel class of nonequilibrium soft materials with examples across a wide range of biological and physical systems including flocking animals [2][3][4], vibrated granular beds [5], synthetic colloidal swimmers [6,7], and a self-propelled cytoskeleton [8,9]. The behavior of spherical tracers in active fluids is most clearly illustrated by the diffusion of colloidal spheres in suspensions of swimming microorganisms [10][11][12][13][14][15][16][17][18]. Because of the hydrodynamic and steric interactions [19][20][21][22][23], a colloidal particle immersed in a bath of microswimmers exhibits a super-diffusive behavior at short times and a dramatically enhanced translational diffusion at long times.…”

mentioning

confidence: 99%

“…The enhanced diffusion of passive particles such as nutrient granules, dead bacterial bodies and extracellular products is of great biological importance, which maintains an active ecological balance [10], stimulates bio-mixing [17], and promotes intercellular signaling and metabolite transports [23]. However, few natural particles have the perfect spherical symmetry and usually possess more than translational degrees of freedom.…”

mentioning

confidence: 99%

Diffusion of Ellipsoids in Bacterial Suspensions

et al. 2016

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Active fluids such as swarming bacteria and motile colloids exhibit exotic properties different from conventional equilibrium materials. As a peculiar example, a spherical tracer immersed inside active fluids shows an enhanced translational diffusion, orders of magnitude stronger than its intrinsic Brownian motion. Here, rather than spherical tracers, we investigate the diffusion of isolated ellipsoids in a quasi-two-dimensional bacterial bath. Our study shows a nonlinear enhancement of both translational and rotational diffusions of ellipsoids. More importantly, we uncover an anomalous coupling between particles' translation and rotation that is strictly prohibited in Brownian diffusion. The coupling reveals a counterintuitive anisotropic particle diffusion, where an ellipsoid diffuses fastest along its minor axis in its body frame. Combining experiments with theoretical modeling, we show that such an anomalous diffusive behavior arises from the generic straining flow of swimming bacteria. Our work illustrates an unexpected feature of active fluids and deepens our understanding of transport processes in microbiological systems.

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Multistep Crystallization and Melting Pathways in the Free‐Energy Landscape of a Au–Si Eutectic Alloy

Kurtuldu

Löffler

2020

Advanced Science

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Crystals do eventually melt if they are heated to their characteristic melting point. However, this is practically only the case for high‐temperature stable crystals, whereas low‐temperature metastable crystals generally transform, before melting, into a more stable solid during heating. Here, it is illustrated that low‐temperature crystals can, however, be melted via fast differential scanning calorimetry (FDSC), even in metallic systems where nucleation and growth kinetics are rapid. For a Au–Si eutectic alloy, various metastable and stable solid states, i.e., (Au–α), (Au–β), γ, and (Au–Si), which form under well‐controlled conditions and melt at high heating rates by preventing the metastable‐to‐stable solid phase transition, are isolated. It is demonstrated that Au81.4Si18.6 can fully melt at various temperatures, i.e., 294 °C, 312 °C, 352 °C, and 363 °C, with differing melting enthalpies ranging from 6.52 to 9.83 kJ mol−1. The melting and crystallization paths of the metastable solids are determined by constructing an energy−temperature diagram. This approach advances the general understanding of nucleation in metallic and other systems, and is expected to contribute to the detailed understanding of thermophysical phenomena that occur at spatially reduced dimensions and/or short time scales, for example in thin‐film deposition, nanomaterials production, or additive manufacturing.

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Metastable quasicrystal-induced nucleation in a bulk glass-forming liquid

Cited by 43 publications

References 59 publications

Multi‐Step Crystallization of Self‐Organized Spiral Eutectics

Multi‐Step Crystallization of Self‐Organized Spiral Eutectics

Diffusion of Ellipsoids in Bacterial Suspensions

Multistep Crystallization and Melting Pathways in the Free‐Energy Landscape of a Au–Si Eutectic Alloy

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