Probing the Equilibrium Dynamics of Colloidal Hard Spheres above the Mode-Coupling Glass Transition

G. Brambilla; D. El Masri; M. Pierno; L. Berthier; L. Cipelletti; G. Petekidis; Andrew B Schofield

doi:10.1103/PhysRevLett.102.085703

Probing the Equilibrium Dynamics of Colloidal Hard Spheres above the Mode-Coupling Glass Transition

G. Brambilla, D. El Masri, M. Pierno, L. Berthier, L. Cipelletti, G. Petekidis, Andrew B Schofield

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract / Description of output

We use dynamic light scattering and computer simulations to study equilibrium dynamics and dynamic heterogeneity in concentrated suspensions of colloidal hard spheres. Our study covers an unprecedented density range and spans seven decades in structural relaxation time, tau(alpha), including equilibrium measurements above phi(c), the location of the glass transition deduced from fitting our data to mode-coupling theory. Instead of falling out of equilibrium, the system remains ergodic above phi(c) and enters a new dynamical regime where tau(alpha) increases with a functional form that was not anticipated by previous experiments, while the amplitude of dynamic heterogeneity grows slower than a power law with tau(alpha), as found in molecular glass formers close to the glass transition.

Original language	English
Article number	085703
Pages (from-to)	-
Number of pages	4
Journal	Physical Review Letters
Volume	102
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevLett.102.085703
Publication status	Published - 27 Feb 2009

Keywords / Materials (for Non-textual outputs)

SCATTERING FUNCTION
SUSPENSIONS
PARTICLES
LIQUIDS
SPECTROSCOPY
STATE

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10.1103/PhysRevLett.102.085703

Cite this

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title = "Probing the Equilibrium Dynamics of Colloidal Hard Spheres above the Mode-Coupling Glass Transition",

abstract = "We use dynamic light scattering and computer simulations to study equilibrium dynamics and dynamic heterogeneity in concentrated suspensions of colloidal hard spheres. Our study covers an unprecedented density range and spans seven decades in structural relaxation time, tau(alpha), including equilibrium measurements above phi(c), the location of the glass transition deduced from fitting our data to mode-coupling theory. Instead of falling out of equilibrium, the system remains ergodic above phi(c) and enters a new dynamical regime where tau(alpha) increases with a functional form that was not anticipated by previous experiments, while the amplitude of dynamic heterogeneity grows slower than a power law with tau(alpha), as found in molecular glass formers close to the glass transition.",

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AU - Brambilla, G.

AU - El Masri, D.

AU - Pierno, M.

AU - Berthier, L.

AU - Cipelletti, L.

AU - Petekidis, G.

AU - Schofield, Andrew B

PY - 2009/2/27

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N2 - We use dynamic light scattering and computer simulations to study equilibrium dynamics and dynamic heterogeneity in concentrated suspensions of colloidal hard spheres. Our study covers an unprecedented density range and spans seven decades in structural relaxation time, tau(alpha), including equilibrium measurements above phi(c), the location of the glass transition deduced from fitting our data to mode-coupling theory. Instead of falling out of equilibrium, the system remains ergodic above phi(c) and enters a new dynamical regime where tau(alpha) increases with a functional form that was not anticipated by previous experiments, while the amplitude of dynamic heterogeneity grows slower than a power law with tau(alpha), as found in molecular glass formers close to the glass transition.

AB - We use dynamic light scattering and computer simulations to study equilibrium dynamics and dynamic heterogeneity in concentrated suspensions of colloidal hard spheres. Our study covers an unprecedented density range and spans seven decades in structural relaxation time, tau(alpha), including equilibrium measurements above phi(c), the location of the glass transition deduced from fitting our data to mode-coupling theory. Instead of falling out of equilibrium, the system remains ergodic above phi(c) and enters a new dynamical regime where tau(alpha) increases with a functional form that was not anticipated by previous experiments, while the amplitude of dynamic heterogeneity grows slower than a power law with tau(alpha), as found in molecular glass formers close to the glass transition.

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KW - SUSPENSIONS

KW - PARTICLES

KW - LIQUIDS

KW - SPECTROSCOPY

KW - STATE

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Probing the Equilibrium Dynamics of Colloidal Hard Spheres above the Mode-Coupling Glass Transition

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Edinbugrh Soft Matter and Statistical Physics Programme Grant Renewal

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Probing the Equilibrium Dynamics of Colloidal Hard Spheres above the Mode-Coupling Glass Transition

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Keywords / Materials (for Non-textual outputs)

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Edinbugrh Soft Matter and Statistical Physics Programme Grant Renewal

Cite this