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Integration of machine learning with neutron scattering for the Hamiltonian tuning of spin ice under pressure

Anjana Samarakoon, D. M. Tennant, Feng Ye, Qiang Zhang, S. A. Grigera

2022Communications Materials22 citationsDOIOpen Access PDF

Abstract

Abstract Quantum materials research requires co-design of theory with experiments and involves demanding simulations and the analysis of vast quantities of data, usually including pattern recognition and clustering. Artificial intelligence is a natural route to optimise these processes and bring theory and experiments together. Here, we propose a scheme that integrates machine learning with high-performance simulations and scattering measurements, covering the pipeline of typical neutron experiments. Our approach uses nonlinear autoencoders trained on realistic simulations along with a fast surrogate for the calculation of scattering in the form of a generative model. We demonstrate this approach in a highly frustrated magnet, Dy 2 Ti 2 O 7 , using machine learning predictions to guide the neutron scattering experiment under hydrostatic pressure, extract material parameters and construct a phase diagram. Our scheme provides a comprehensive set of capabilities that allows direct integration of theory along with automated data processing and provides on a rapid timescale direct insight into a challenging condensed matter system.

Topics & Concepts

Neutron scatteringComputer scienceArtificial neural networkScatteringPipeline (software)Artificial intelligenceMachine learningComputational sciencePhysicsStatistical physicsQuantum mechanicsProgramming languageAdvanced Condensed Matter PhysicsPhysics of Superconductivity and MagnetismQuantum many-body systems
Integration of machine learning with neutron scattering for the Hamiltonian tuning of spin ice under pressure | Litcius