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Statistical Physics through the Lens of Real-Space Mutual Information

Doruk Efe Gökmen, Zohar Ringel, Sebastian D. Huber, Maciej Koch-Janusz

2021Physical Review Letters20 citationsDOIOpen Access PDF

Abstract

Identifying the relevant degrees of freedom in a complex physical system is a key stage in developing effective theories in and out of equilibrium. The celebrated renormalization group provides a framework for this, but its practical execution in unfamiliar systems is fraught with ad hoc choices, whereas machine learning approaches, though promising, lack formal interpretability. Here we present an algorithm employing state-of-the-art results in machine-learning-based estimation of information-theoretic quantities, overcoming these challenges, and use this advance to develop a new paradigm in identifying the most relevant operators describing properties of the system. We demonstrate this on an interacting model, where the emergent degrees of freedom are qualitatively different from the microscopic constituents. Our results push the boundary of formally interpretable applications of machine learning, conceptually paving the way toward automated theory building.

Topics & Concepts

Degrees of freedom (physics and chemistry)Computer scienceThrough-the-lens meteringMutual informationKey (lock)Boundary (topology)Information theoryRenormalizationRenormalization groupArtificial intelligenceTheoretical computer scienceLens (geology)Statistical physicsPhysicsTheoretical physicsMachine learningPhysical systemAlgorithmComplex systemMeasure (data warehouse)Probability and statisticsAdvanced Thermodynamics and Statistical MechanicsStatistical Mechanics and EntropyQuantum many-body systems
Statistical Physics through the Lens of Real-Space Mutual Information | Litcius