Litcius/Paper detail

Machine learning for exploring small polaron configurational space

Viktor C. Birschitzky, Florian Ellinger, Ulrike Diebold, Michele Reticcioli, Cesare Franchini

2022npj Computational Materials19 citationsDOIOpen Access PDF

Abstract

Abstract Polaron defects are ubiquitous in materials and play an important role in many processes involving carrier mobility, charge transfer and surface reactivity. Determining small polarons’ spatial distributions is essential to understand materials properties and functionalities. However, the required exploration of the configurational space is computationally demanding when using first principles methods. Here, we propose a machine-learning (ML) accelerated search that determines the ground state polaronic configuration. The ML model is trained on databases of polaron configurations generated by density functional theory (DFT) via molecular dynamics or random sampling. To establish a mapping between configurations and their stability, we designed descriptors modelling the interactions among polarons and charged point defects. We used the DFT+ML protocol to explore the polaron configurational space for two surface-systems, reduced rutile TiO 2 (110) and Nb-doped SrTiO 3 (001). The ML-aided search proposes additional polaronic configurations and can be utilized to determine optimal polaron distributions at any charge concentration.

Topics & Concepts

PolaronDensity functional theorySpace (punctuation)Charge (physics)Computer scienceStability (learning theory)Chemical physicsMaterials scienceStatistical physicsPhysicsComputational chemistryChemistryQuantum mechanicsMachine learningElectronOperating systemMachine Learning in Materials ScienceElectronic and Structural Properties of OxidesX-ray Diffraction in Crystallography