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Path integral approach unveils role of complex energy landscape for activated dynamics of glassy systems

Tommaso Rizzo

2021Physical review. B./Physical review. B25 citationsDOIOpen Access PDF

Abstract

The complex dynamics of an increasing number of systems is attributed to the emergence of a rugged energy landscape with an exponential number of metastable states. To develop this picture into a predictive dynamical theory I discuss how to compute the exponentially small probability of a jump from one metastable state to another. This is expressed as a path integral that can be evaluated by saddle-point methods in mean-field models, leading to a boundary value problem. The resulting dynamical equations are solved numerically by means of a Newton-Krylov algorithm in the paradigmatic spherical $p$-spin glass model that is invoked in diverse contexts from supercooled liquids to machine-learning algorithms. I discuss the solutions in the asymptotic regime of large times and the physical implications on the nature of the ergodicity-restoring processes.

Topics & Concepts

Saddle pointMetastabilityEnergy landscapeStatistical physicsSpinodalErgodicityPath integral formulationComplex systemJumpDynamical systems theoryExponential functionBoundary (topology)MathematicsApplied mathematicsPhysicsComputer scienceMathematical analysisGeometryQuantum mechanicsPhase (matter)QuantumArtificial intelligenceThermodynamicsMaterial Dynamics and PropertiesTheoretical and Computational PhysicsComplex Systems and Time Series Analysis
Path integral approach unveils role of complex energy landscape for activated dynamics of glassy systems | Litcius