Viscosity of chalcogenide glass-formers

Košťál, Petr; Shánělová, Jana; Málek, Jiřı́

doi:10.1080/09506608.2018.1564545

Cited by 28 publications

(20 citation statements)

References 178 publications

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“…The long-range diffusion/viscous flow, ≳ 1000 K, shows a much higher activation barrier, ≈1.2 eV, comparable with that found in macroscopic viscosity measurements. 91,92 The observed difference is well illustrated by two snapshots of the FPMD simulation boxes taken at 300 K and 1300 K, the insets in Fig. 12(e).…”

Section: Accepted Manuscriptmentioning

confidence: 72%

Glassy GaS: transparent and unusually rigid thin films for visible to mid-IR memory applications

Tverjanovich

Khomenko

Bereznev

et al. 2020

Phys. Chem. Chem. Phys.

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Section: Accepted Manuscriptmentioning

confidence: 72%

Glassy GaS: transparent and unusually rigid thin films for visible to mid-IR memory applications

Tverjanovich

Khomenko

Bereznev

et al. 2020

Phys. Chem. Chem. Phys.

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“…The current idea on the 1D liquids may be extended to 0D and 2D materials. For instance, it has been demonstrated that small molecules, e.g., orthoterphenyl, are fragile with m % 80, [6,7,10,14,16] but the character may be affected by intramolecular relaxations. Are elemental van der Waals fluids such as Ar also fragile?…”

Section: Discussionmentioning

confidence: 99%

“…In brief, related backgrounds can be summarized as follows: It is known that η ( T ) in (supercooled) liquids leading to the glass transition can be approximated using the Vogel–Fulcher–Tammann (VFT) equation

η (T) = η_{\infty} \exp {B / (T - T_{0})}

where η ∞ (=10 −4 P = 10 −5 Pa s) is an empirically chosen viscosity at sufficiently high temperatures, B represents an activation temperature, and T 0 is referred to as the Vogel temperature, which appears to be nearly equal to the Kauzmann temperature T K . In Equation , if T 0 = 0, it reduces to the Arrhenius type, an approximate form appearing in the so‐called “strong” liquid such as SiO 2 .…”

Section: Fundamentalsmentioning

confidence: 99%

“…[1,2] Among these, the fragility with a steepness index m, which works as a good metric characterizing the viscosity η (¼1/fluidity) variation with temperature T in (supercooled) liquids, [3] has been grasped as an important parameter preluding the glass transition. Actually, extensive studies have been performed for uncovering and understanding relations between the index and other variables including density, [4] elasticity, [5,6] chemical composition, [7,8] enthalpy relaxation, [9] glasstransition temperature, [10][11][12] topological structure, [4,[13][14][15] and stretched exponential factor. [16][17][18] However, still elusive is the interpretation of the fragility in terms of microscopic structures.…”

Section: Introductionmentioning

confidence: 99%

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Fragility of 1D Floppy Materials

Tanaka

2020

Physica Status Solidi (b)

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The fragility works as a fundamental concept characterizing glass‐forming liquids, whereas its atomic structural interpretation remains a challenge. Herein, viscosity behaviors in polyethylene (PE), S, Se, and Te are examined, which consist of distorted chain molecules with varied interchain strength, in comparison with that in SiO2, a typical strong material. Among the 1D materials, S and PE appear to be fairly strong. Such results suggest that the viscosity exhibits Arrhenius‐type behaviourif it is governed by single microscopic mechanisms such as SiO bond scission or interchain slippages. In contrast, Se and Te appear fragile with non‐Arrhenius variations, which could be ascribable to mixed inter‐ and intrachain interactions. Among these floppy materials, it is known that Se is the best glass former, the reason being discussed.

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“…Nevertheless, according to our opinion and experiences, this is the reasonable way to extrapolate viscosity data if melt viscosities are unknown. The different viscosity equations were tested in our work submitted for publishing [39]. Well-described chalcogenide amorphous materials (As2S3, As2Se3, Se) with measured viscosities in melt region were fitted by VFT [40][41][42] (Vogel-Fulcher-Tammann), MYEGA [43] (Mauro-Yue-Ellison-Gupta-Allan) and Ojovan [44] equations.…”

Section: Temperature Dependence Of Viscositymentioning

confidence: 99%

Analysis of crystal growth and viscosity in Ge-Sb-Se-Te undercooled melts

Barták

Košťál

Málek

2019

Journal of Non-Crystalline Solids

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A comprehensive analysis on crystal growth and viscosity is presented for the Ge2Sb2Se5-xTex (x = 0.5 and 1) undercooled melts in this article. Temperature dependence of the measured viscosities (10 7.5 -10 12.5 Pa•s) can be described by a simple exponential Arrhenius type equation in the relatively narrow temperature region in which the measurements were performed. Fragility of the measured materials are all roughly equal to 43, which means that these materials belong to the so called "intermediate" liquids (lying in the middle between strong and fragile liquids) and cannot be described by simple Arrhenius type equation if the temperature region is expanded from glass transition to melting, which is important for description of crystal growth. Therefore, MYEGA equation is used to extrapolate the viscosity data into the temperature region of studied crystal growth. Nucleation and crystal growth started on a surface of studied samples. The isothermal growth rate of the formed surface crystalline layer was measured at various temperatures. Analysis of the growth data revealed a crystal growth driven by liquid-crystal interface kinetics. Therefore, the standard crystal growth models were used for description of crystal growth rates in the studied systems.

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Viscosity of chalcogenide glass-formers

Cited by 28 publications

References 178 publications

Glassy GaS: transparent and unusually rigid thin films for visible to mid-IR memory applications

Glassy GaS: transparent and unusually rigid thin films for visible to mid-IR memory applications

Fragility of 1D Floppy Materials

Analysis of crystal growth and viscosity in Ge-Sb-Se-Te undercooled melts

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