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Unsupervised identification of topological phase transitions using predictive models

Eliška Greplová, Agnes Valenti, Gregor Boschung, Frank Schäfer, Niels Lörch, Sebastian D. Huber

2020Repository for Publications and Research Data (ETH Zurich)60 citationsDOIOpen Access PDF

Abstract

Machine-learning driven models have proven to be powerful tools for the identification of phases of matter. In particular, unsupervised methods hold the promise to help discover new phases of matter without the need for any prior theoretical knowledge. While for phases characterized by a broken symmetry, the use of unsupervised methods has proven to be successful, topological phases without a local order parameter seem to be much harder to identify without supervision. Here, we use an unsupervised approach to identify boundaries of the topological phases. We train artificial neural nets to relate configurational data or measurement outcomes to quantities like temperature or tuning parameters in the Hamiltonian. The accuracy of these predictive models can then serve as an indicator for phase transitions. We successfully illustrate this approach on both the classical Ising gauge theory as well as on the quantum ground state of a generalized toric code.

Topics & Concepts

PhysicsIsing modelToric codeUnsupervised learningHamiltonian (control theory)Identification (biology)Artificial neural networkPhase transitionTopology (electrical circuits)QuantumTopological orderStatistical physicsArtificial intelligenceMachine learningTheoretical physicsQuantum mechanicsComputer scienceCombinatoricsMathematicsMathematical optimizationBotanyBiologyQuantum many-body systemsTheoretical and Computational PhysicsMachine Learning in Materials Science
Unsupervised identification of topological phase transitions using predictive models | Litcius