Litcius/Paper detail

Hyperactive learning for data-driven interatomic potentials

Cas van der Oord, Matthias Sachs, Dávid Péter Kovács, Christoph Ortner, Gábor Cśanyi

2023npj Computational Materials102 citationsDOIOpen Access PDF

Abstract

Data-driven interatomic potentials have emerged as a powerful tool for approximating ab initio potential energy surfaces. The most time-consuming step in creating these interatomic potentials is typically the generation of a suitable training database. To aid this process hyperactive learning (HAL), an accelerated active learning scheme, is presented as a method for rapid automated training database assembly. HAL adds a biasing term to a physically motivated sampler (e.g. molecular dynamics) driving atomic structures towards uncertainty in turn generating unseen or valuable training configurations. The proposed HAL framework is used to develop atomic cluster expansion (ACE) interatomic potentials for the AlSi10 alloy and polyethylene glycol (PEG) polymer starting from roughly a dozen initial configurations. The HAL generated ACE potentials are shown to be able to determine macroscopic properties, such as melting temperature and density, with close to experimental accuracy.

Topics & Concepts

Interatomic potentialAb initioMolecular dynamicsPolyethylene glycolCluster (spacecraft)Process (computing)Statistical physicsMaterials scienceComputer scienceChemical physicsMolecular physicsChemistryPhysicsComputational chemistryQuantum mechanicsOperating systemProgramming languageOrganic chemistryMachine Learning in Materials ScienceX-ray Diffraction in CrystallographyCrystallography and molecular interactions