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Unexpected thermal conductivity enhancement in aperiodic superlattices discovered using active machine learning

Prabudhya Roy Chowdhury, Xiulin Ruan

2022npj Computational Materials26 citationsDOIOpen Access PDF

Abstract

Abstract While machine learning (ML) has shown increasing effectiveness in optimizing materials properties under known physics, its application in discovering new physics remains challenging due to its interpolative nature. In this work, we demonstrate a general-purpose adaptive ML-accelerated search process that can discover unexpected lattice thermal conductivity ( κ l ) enhancement in aperiodic superlattices (SLs) as compared to periodic superlattices, with implications for thermal management of multilayer-based electronic devices. We use molecular dynamics simulations for high-fidelity calculations of κ l , along with a convolutional neural network (CNN) which can rapidly predict κ l for a large number of structures. To ensure accurate prediction for the target unknown SLs, we iteratively identify aperiodic SLs with structural features leading to locally enhanced thermal transport and include them as additional training data for the CNN. The identified structures exhibit increased coherent phonon transport owing to the presence of closely spaced interfaces.

Topics & Concepts

Aperiodic graphSuperlatticeThermal conductivityConvolutional neural networkPhononLattice (music)Computer scienceThermalMaterials scienceArtificial intelligenceStatistical physicsPhysicsCondensed matter physicsOptoelectronicsMathematicsThermodynamicsAcousticsComposite materialCombinatoricsThermal properties of materialsAdvanced Thermoelectric Materials and DevicesMachine Learning in Materials Science