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Modelling atomic and nanoscale structure in the silicon–oxygen system through active machine learning

Linus C. Erhard, Jochen Rohrer, Karsten Albe, Volker L. Deringer

2024Nature Communications69 citationsDOIOpen Access PDF

Abstract

Silicon-oxygen compounds are among the most important ones in the natural sciences, occurring as building blocks in minerals and being used in semiconductors and catalysis. Beyond the well-known silicon dioxide, there are phases with different stoichiometric composition and nanostructured composites. One of the key challenges in understanding the Si-O system is therefore to accurately account for its nanoscale heterogeneity beyond the length scale of individual atoms. Here we show that a unified computational description of the full Si-O system is indeed possible, based on atomistic machine learning coupled to an active-learning workflow. We showcase applications to very-high-pressure silica, to surfaces and aerogels, and to the structure of amorphous silicon monoxide. In a wider context, our work illustrates how structural complexity in functional materials beyond the atomic and few-nanometre length scales can be captured with active machine learning.

Topics & Concepts

SiliconContext (archaeology)Nanoscopic scaleNanotechnologyAmorphous silicaMaterials scienceWorkflowNanometreAtomic unitsSilicon dioxideSemiconductorAmorphous solidScale (ratio)Computer scienceChemistryChemical engineeringPhysicsOptoelectronicsCrystallographyEngineeringBiologyQuantum mechanicsDatabaseMetallurgyComposite materialPaleontologyElectronic and Structural Properties of OxidesMachine Learning in Materials ScienceDiamond and Carbon-based Materials Research
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