Although several theories relate the steep slowdown of glass formers to
increasing spatial correlations of some sort, standard static correlation
functions show no evidence for this. We present results that reveal for the
first time a qualitative thermodynamic difference between the high temperature
and deeply supercooled equilibrium glass-forming liquid: the influence of
boundary conditions propagates into the bulk over larger and larger
lengthscales upon cooling, and, as this static correlation length grows, the
influence decays nonexponentially. Increasingly long-range susceptibility to
boundary conditions is expected within the random firt-order theory (RFOT) of
the glass transition, but a quantitative account of our numerical results
requires a generalization of RFOT where the surface tension between states
fluctuates

A Cavagna

A Montanari

A. Cavagna

B Bernu

B Coluzzi

C Cammarota

C Toninelli

D Kivelson

G Adam

G Tarjus

G. Biroli

J-N Roux

J-P Bouchaud

J.-P. Bouchaud

JD Stevenson

JH Gibbs

JP Garrahan

L Berthier

LA Fernández

M Dzero

M Mézard

MA Moore

MD Ediger

N Menon

P Scheidler

P. Verrocchio

RL Jack

RL Leheny

S Franz

T. S. Grigera

TR Kirkpatrick

TS Grigera

English

arXiv

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Thermodynamic signature of growing amorphous order in glass-forming liquids

That the dynamical properties of a glass-forming liquid at high temperature are different from behaviour in the supercooled state has already been established. Numerical simulations now suggest that the static length scale over which spatial correlations exist also changes on approaching the glass transition. Supercooled liquids exhibit a pronounced slowdown of their dynamics on cooling1 without showing any obvious structural or thermodynamic changes2. Several theories relate this slowdown to increasing spatial correlations3,4,5,6. However, no sign of this is seen in standard static correlation functions, despite indirect evidence from considering specific heat7 and linear dielectric susceptibility8. Whereas the dynamic correlation function progressively becomes more non-exponential as the temperature is reduced, so far no similar signature has been found in static correlations that can distinguish qualitatively between a high-temperature and a deeply supercooled glass-forming liquid in equilibrium. Here, we show evidence of a qualitative thermodynamic signature that differentiates between the two. We show by numerical simulations with fixed boundary conditions that the influence of the boundary propagates into the bulk over increasing length scales on cooling. With the increase of this static correlation length, the influence of the boundary decays non-exponentially. Such long-range susceptibility to boundary conditions is expected within the random first-order theory4,9,10 (RFOT) of the glass transition. However, a quantitative account of our numerical results requires a generalization of RFOT, taking into account surface tension fluctuations between states.Instituto de Investigaciones Fisicoquímicas Teóricas y Aplicada

Biroli, Giulio

Bouchaud, Jean-Philippe

Cavagna, Andrea

Grigera, Tomás Sebastián

Verrocchio, Paolo

LAReferencia - Red Federada de Repositorios Institucionales de Publicaciones Científicas Latinoamericanas

Thermodynamic signature of growing amorphous order in glass-forming
  liquids

Thermodynamic signature of growing amorphous order in glass-forming liquids

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LAReferencia - Red Federada de Repositorios Institucionales de Publicaciones Científicas Latinoamericanas