Rigidity Percolation and Molecular Clustering in Network Glasses

9 June 1986

journal article
research article
Published by American Physical Society (APS) in Physical Review Letters

Vol. 56 (23) , 2493-2496
https://doi.org/10.1103/physrevlett.56.2493

Abstract

{}^{129}I

Mössbauer spectra of

g - {Ge}_{x} {Se}_{1 - x}

alloys display a local maximum in the site-intensity ratio

\frac{I_{B}}{I_{A}} (x)

at the critical composition

x = x_{c} = 0.23 \pm 0.02

. This observation is consistent with the realization of mechanical critical behavior in a covalent network glass recently predicted by Phillips and Thorpe. We identify

x_{c}

with the onset of percolation of a specific molecular fragment based on the layered form of

c - Ge {Se}_{2}

Keywords

This publication has 18 references indexed in Scilit:

Vibrational thresholds near critical average coordination in alloy network glasses
Physical Review B, 1985
Constraint theory, vector percolation and glass formation
Solid State Communications, 1985
Investigation of stability of (Ge, Sn)-(S, or Se) cluster vibrational spectra
Journal of Non-Crystalline Solids, 1983
Continuous deformations in random networks
Journal of Non-Crystalline Solids, 1983
Glass formation and properties of chalcogenide systems XXVI: Permittivity and the structure of glasses AsxSe1−x and GexSe1−x
Journal of Non-Crystalline Solids, 1983
Broken chemical order and phase separation in GexSe1−x glasses
Solid State Communications, 1983
Structural origin of broken chemical order in a Ge ${Se}_{2}$ glass
Physical Review B, 1982
Direct Evidence for Intrinsically Broken Chemical Ordering in Melt-Quenched Glasses
Physical Review Letters, 1981
Topology of covalent non-crystalline solids II: Medium-range order in chalcogenide alloys and ASi(Ge)
Journal of Non-Crystalline Solids, 1981
Topology of covalent non-crystalline solids I: Short-range order in chalcogenide alloys
Journal of Non-Crystalline Solids, 1979