Gardner physics in amorphous solids and beyond.

Date
2019-07
Authors
Berthier, Ludovic
Biroli, Giulio
Charbonneau, Patrick
Corwin, Eric I
Franz, Silvio
Zamponi, Francesco
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Abstract
One of the most remarkable predictions to emerge out of the exact infinite-dimensional solution of the glass problem is the Gardner transition. Although this transition was first theoretically proposed a generation ago for certain mean-field spin glass models, its materials relevance was only realized when a systematic effort to relate glass formation and jamming was undertaken. A number of nontrivial physical signatures associated with the Gardner transition have since been considered in various areas, from models of structural glasses to constraint satisfaction problems. This perspective surveys these recent advances and discusses the novel research opportunities that arise from them.
Type
Journal article
Subject
Science & Technology
Physical Sciences
Chemistry, Physical
Physics, Atomic, Molecular & Chemical
Chemistry
Physics
MEAN-FIELD-THEORY
SPIN-GLASS
VIBRATIONAL PROPERTIES
METASTABLE STATES
VISCOUS-LIQUIDS
SOLVABLE MODEL
TRANSITION
DYNAMICS
PHASE
CONNECTIONS
Permalink
https://hdl.handle.net/10161/24990
Published Version (Please cite this version)
10.1063/1.5097175
Publication Info
Berthier, Ludovic; Biroli, Giulio; Charbonneau, Patrick; Corwin, Eric I; Franz, Silvio; & Zamponi, Francesco (2019). Gardner physics in amorphous solids and beyond. The Journal of chemical physics, 151(1). pp. 010901. 10.1063/1.5097175. Retrieved from https://hdl.handle.net/10161/24990.
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Scholars@Duke

Charbonneau

Patrick Charbonneau

Professor of Chemistry
Professor Charbonneau studies soft matter. His work combines theory and simulation to understand the glass problem, protein crystallization, microphase formation, and colloidal assembly in external fields.
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