Universality of the high-temperature viscosity limit of silicate liquids

Zheng, Qiuju; Mauro, John C.; Ellison, Adam J.; Potužák, Marcel; Yue, Yuanzheng

doi:10.1103/physrevb.83.212202

Cited by 93 publications

(103 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, the high-temperature viscosity limit has recently been shown to be composition independent and equal to approximately 10 − 3 Pa·s [34]. With these definitions of glass transition temperature, high-temperature viscosity limit, and fragility, Eq.…”

Section: Rheological Propertiesmentioning

confidence: 96%

Composition–structure–property relationships in boroaluminosilicate glasses

Zheng¹,

Potužák²,

Mauro³

et al. 2012

Journal of Non-Crystalline Solids

Self Cite

103

View full text Add to dashboard Cite

Section: Rheological Propertiesmentioning

confidence: 96%

Composition–structure–property relationships in boroaluminosilicate glasses

Zheng¹,

Potužák²,

Mauro³

et al. 2012

Journal of Non-Crystalline Solids

Self Cite

103

View full text Add to dashboard Cite

“…An analysis of viscosity curves [19] using a convenient fitting formula for silicate liquids and other liquids including metallic, molecular, and ionic systems, has shown that the high-temperature viscosity limit of such liquids is about 10 −2.93 Pa.s [19]. As there seems to be no systematic dependence of η ∞ on composition, at least for the silicates given the narrow spread around the average value of 10 −2.93 Pa.s, it is believed that η ∞ has some kind of a universal character.…”

Section: ≡mentioning

confidence: 99%

“…The labels on the x-axis refer to all possible triplets i0j between a central atom 0 and two neighbors i and j. For all systems, the PBADs relative to the Group IV (Si, Ge) atom have a low standard deviation σ θ , of the order of [10][11][12][13][14][15][16][17][18][19][20] o when the first four neighbours are considered. One finds e.g.…”

Section: Bond-bendingmentioning

confidence: 99%

Relaxation and physical aging in network glasses: a review

Micoulaut

2016

Rep. Prog. Phys.

View full text Add to dashboard Cite

Abstract. Recent progresses in the description of glassy relaxation and ageing are reviewed for the wide class of network-forming materials such as GeO 2 , Ge x Se 1−x , silicates (SiO 2 -Na 2 O) or borates (B 2 O 3 -Li 2 O), all of them having an important usefulness in domestic, geological or optoelectronic applications. A brief introduction of the glass transition phenomenology is given, together with the salient features that are revealed both from theory and experiments. Standard experimental methods used for the characterization of the slowing down of the dynamics are reviewed. We then discuss the important role played by aspect of network topology and rigidity for the understanding of the relaxation of the glass transition, while also permitting analytical predictions of glass properties from simple and insightful models based on the network structure. We also emphasize the great utility of computer simulations which probe the dynamics at the molecular level, and permit to calculate various structure-related functions in connection with glassy relaxation and the physics of ageing which reveals the off-equilibrium nature of glasses. We discuss the notion of spatial variations of structure which leads to the picture of "dynamic heterogeneities", and recent results of this important topic for network glasses are also reviewed.PACS numbers: 61.43. Fs, 64.70.kj Relaxation and physical ageing in network glasses 2 Figure 1. Typical network-forming glasses: a) A stoichiometric glass former (SiO 2 , B 2 S 3 ) whose structure and network connectivity can be altered by the addition (b) of 2-fold coordinated atoms (usually chalcogens, S, Se) that lead to cross-linked chains. The structure can also be depolymerized (c) by the addition of a network modifier (alkali oxides or chalcogenides, Na 2 O, Li 2 S, etc.). Glassy dynamics depends strongly on the network topology, i.e. the way bonds and angles arrange to lead to a connected atomic network. Note that only chalcogenides can produce a mixture of these three kinds of basic networks, e.g. (1-x)Ge y Se 1−y -xAg 2 Se [2], and for the latter system x=0 corresponds to case (b), y=33% corresponds to case (c), and both conditions together (x=0,y=33 %) to case (a).

show abstract

“…The model was used to fit the measured viscosity data for Se (Cukierman and Uhlmann, 1973;Koštál and Málek, 2010;Gueguen et al, 2011), Ge 0.10 Se 0.90 (Nemilov, 1964;Senapati and Varshneya, 1996;Gueguen et al, 2011), Ge 0.20 Se 0.80 (Nemilov, 1964;Gueguen et al, 2011), and Ge 0.25 Se 0.75 (Nemilov, 1964;Senapati and Varshneya, 1996;Gueguen et al, 2011) where two or more of the data sets are self-consistent, and the measured viscosity data for Ge 0.30 Se 0.70 (Gueguen et al, 2011) where only one data set is available. For a given composition, the logarithm of the high-temperature viscosity was treated as either a fitting parameter or a fixed parameter set at log 10 [η ∞ (Pa s)] = − 2.93 (Zheng et al, 2011). The fits corresponding to log 10 [η ∞ (Pa s)] = − 2.93 are shown in Figure 11, and give values of T g and m visc (Figure 12) that are within the spread of values reported in the literature from viscosity measurements ( Table 1).…”

Section: Viscosity and Fragility Indexmentioning

confidence: 99%

Topological Ordering and Viscosity in the Glass-Forming Ge–Se System: The Search for a Structural or Dynamical Signature of the Intermediate Phase

et al. 2017

View full text Add to dashboard Cite

The topological ordering of the network structure in vitreous Ge x Se 1−x was investigated across most of the glass-forming region (0 ≤ x ≤ 0.4) by using high-resolution neutron diffraction to measure the Bhatia-Thornton number-number partial structure factor. This approach gives access to the composition dependence of the mean coordination number n and correlation lengths associated with the network ordering. The thermal properties of the samples were also measured by using temperature-modulated differential scanning calorimetry. The results do not point to a structural origin of the so-called intermediate phase, which in our work is indicated for the composition range 0.175(8) ≤ x ≤ 0.235(8) by a vanishingly small non-reversing enthalpy near the glass transition. The midpoint of this range coincides with the mean-field expectation of a floppy-to-rigid transition at x = 0.20. The composition dependence of the liquid viscosity, as taken from the literature, was also investigated to look for a dynamical origin of the intermediate phase, using the Mauro-YueEllison-Gupta-Allan (MYEGA) model to estimate the viscosity at the liquidus temperature. The evidence points to a maximum in the viscosity at the liquidus temperature, and a minimum in the fragility index, for the range 0.20 ≤ x ≤ 0.22. The utility of the intermediate phase as a predictor of the material properties in network glass-forming systems is discussed.

show abstract

Universality of the high-temperature viscosity limit of silicate liquids

Cited by 93 publications

References 29 publications

Composition–structure–property relationships in boroaluminosilicate glasses

Composition–structure–property relationships in boroaluminosilicate glasses

Relaxation and physical aging in network glasses: a review

Topological Ordering and Viscosity in the Glass-Forming Ge–Se System: The Search for a Structural or Dynamical Signature of the Intermediate Phase

Contact Info

Product

Resources

About