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

Kurtuldu, Güven; Löffler, Jörg F.

doi:10.1002/advs.201903544

Cited by 14 publications

(4 citation statements)

References 34 publications

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“…Upon heating, the DSC curve shows a signal with T onset = 495(10) K ( Figure S1 ). In agreement with ref ( 22 ), this signal corresponds to the start of decomposition of Au 4 Si and formation of Au, although in situ heating experiments with synchrotron radiation (DESY, Hamburg, Germany) revealed that very high-quality crystals of Au 4 Si withstand temperatures of up to 573 K for ∼4 min. At T onset = 635(10) K, an endothermic effect with a corresponding signal in the cooling curve is observed, in line with the T e of the eutectic mixture.…”

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confidence: 89%

Temporary Cohabitation: The Metastable Phase Au₄Si

et al. 2022

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The prediction, identification, and characterization of phases away from equilibrium conditions remain difficult challenges for material science. Herein, we demonstrate how systems whose phase diagrams contain deeply incising eutectics can offer opportunities to address these challenges. We report the synthesis of a new compound in the Au–Si system, a textbook example of a system with a deep eutectic. Au4Si crystallizes in a complex √18×√2×1 superstructure of the PtHg4 type, based on the distortion of vertex-sharing Si@Au8 cubes into bisdisphenoids. Au4Si decomposes upon heating and at room temperature even in high vacuum, highlighting its metastability. Electronic structure analysis reveals a pseudogap at the Fermi energy, which is enhanced by the superstructure through the relief of Au–Au antibonding interactions. The pseudogap is associated with a Zintl-type bonding scheme, which can be extended to the locally ordered liquid. These results highlight the potential for metastable phases to form in deep eutectics that preserve the local structures of the liquid.

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confidence: 89%

Temporary Cohabitation: The Metastable Phase Au₄Si

et al. 2022

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“…The annealing twins and shrinkage cavities formed in Au nano-film could be attributed to the effect of non-uniform high surface tensions, which is similar with the intrinsic stress induced by high strain rolling in metals with low stacking fault energy [16]. During the annealing, the contents of Si atoms solid dissolved into Au nano-film close to the Au/Si interface dominated the number and size of Au-Si eutectics at Au/Si interfaces [17]. The ripening process of Au nano-film provides the opportunity to weld Au nano-film with Si substrate through the formation of Au-Si eutectic.…”

Section: Resultsmentioning

confidence: 80%

Erect Au Nanocones Drawn from Au Nano-Films by Nano-Size Au-Si Eutectic Clamping with High Adhesion to Substrates

Zhao²,

Shi³

et al. 2020

Metals

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Erect Au nanocones with high adhesion to substrates are obtained by simply drawing from Au nano-films through Au-Si eutectic welding. Nanocones with diameters ranging from about 5 to 150 nm and length ranging from about 60 to 600 nm can be observed on both Au and Si substrate surfaces. Nano-scale Au-Si eutectics formed at the rough Au–silicon film interface under annealing at 450 °C and the subsequent cooling process facilitate the formation of nano-bonding points and draw Au nanocones from Au nano-film by mechanical separation. Erect Au nanocones adhered to Au or Si substrates shows higher light enhancement than itself, observed by FDTD simulation. This method provides new strategy for the fabrication of SERS detectors, solar cells et al. with high stability.

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“…18 In recent years, although some theoretical studies reported possible alloy structures of Au-Si, [19][20][21] the local ordering of Au-Si BMG is still lacking. Interestingly, two-dimensional (2D) crystallization was observed at the surface of Au-Si metallic glass, 22,23 which has been experimentally confirmed to be an ordered rectangular structure 22 with the proposed Si-Si bond on the surface. Shpyrko and co-workers 22 claimed that the Au-Si surface ordering was induced by surface-induced freezing, 24 but the ordered prefreezing surface will only appear near the transition temperature rather than a wide range of temperatures, inconsistent with the case of Au-Si.…”

Section: Introductionmentioning

confidence: 89%

Five-fold Symmetry in Au-Si Metallic Glass

He¹,

Xu²,

Qiu³

et al. 2022

Preprint

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The first metallic glass of Au-Si alloy has been discovered for over half a century, but its atomic structure is still puzzling. Herein, Au 8 Si dodecahedrons with local five-fold symmetry are revealed as building blocks in Au-Si metallic glass, and the interconnection modes of Au 8 Si dodecahedrons determine the medium-range order. With dimensionality reduction, the surface ordering is attributed to the motif transformation of Au 8 Si dodecahedrons into planar Au 5 Si pyramids with five-fold symmetry, and thus the self-assembly of Au 5 Si pyramids leads to the formation of the ordered Au 2 Si monolayer with the lowest energy. Furthermore, the structural similarity analysis is performed to unveil the physical origin of structural characteristics in different dimensions. The amorphism of Au-Si is due to the smooth energy landscape around the global minimum, while the ordered surface structure occurs due to the steep energy landscape.

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

Cited by 14 publications

References 34 publications

Temporary Cohabitation: The Metastable Phase Au₄Si

Temporary Cohabitation: The Metastable Phase Au₄Si

Erect Au Nanocones Drawn from Au Nano-Films by Nano-Size Au-Si Eutectic Clamping with High Adhesion to Substrates

Five-fold Symmetry in Au-Si Metallic Glass

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

Cited by 14 publications

References 34 publications

Temporary Cohabitation: The Metastable Phase Au4Si

Temporary Cohabitation: The Metastable Phase Au4Si

Erect Au Nanocones Drawn from Au Nano-Films by Nano-Size Au-Si Eutectic Clamping with High Adhesion to Substrates

Five-fold Symmetry in Au-Si Metallic Glass

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Product

Resources

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Temporary Cohabitation: The Metastable Phase Au₄Si

Temporary Cohabitation: The Metastable Phase Au₄Si