Probing Equilibrium Glass Flow Up to Exapoise Viscosities

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2015 Feb 13

PMID 25675511

Citations 3

Authors

Eva Arianna Aurelia Pogna

Cristian Rodriguez-Tinoco

Giulio Cerullo

Carino Ferrante

Javier Rodriguez-Viejo

Tullio Scopigno

Affiliations

Soon will be listed here.

Abstract

Glasses are out-of-equilibrium systems aging under the crystallization threat. During ordinary glass formation, the atomic diffusion slows down, rendering its experimental investigation impractically long, to the extent that a timescale divergence is taken for granted by many. We circumvent these limitations here, taking advantage of a wide family of glasses rapidly obtained by physical vapor deposition directly into the solid state, endowed with different "ages" rivaling those reached by standard cooling and waiting for millennia. Isothermally probing the mechanical response of each of these glasses, we infer a correspondence with viscosity along the equilibrium line, up to exapoise values. We find a dependence of the elastic modulus on the glass age, which, traced back to the temperature steepness index of the viscosity, tears down one of the cornerstones of several glass transition theories: the dynamical divergence. Critically, our results suggest that the conventional wisdom picture of a glass ceasing to flow at finite temperature could be wrong.

Citing Articles

Testing the paradigm of an ideal glass transition: Dynamics of an ultrastable polymeric glass.

Yoon H, Mckenna G Sci Adv. 2018; 4(12):eaau5423.

PMID: 30588491 PMC: 6303122. DOI: 10.1126/sciadv.aau5423.

Relaxation dynamics of glasses along a wide stability and temperature range.

Rodriguez-Tinoco C, Rafols-Ribe J, Gonzalez-Silveira M, Rodriguez-Viejo J Sci Rep. 2016; 6:35607.

PMID: 27767071 PMC: 5073287. DOI: 10.1038/srep35607.

Ultrastable glasses portray similar behaviour to ordinary glasses at high pressure.

Rodriguez-Tinoco C, Gonzalez-Silveira M, Barrio M, Lloveras P, Tamarit J, Garden J Sci Rep. 2016; 6:34296.

PMID: 27694814 PMC: 5046104. DOI: 10.1038/srep34296.

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