Litcius/Paper detail

Nanohardness from First Principles with Active Learning on Atomic Environments

Evgeny V. Podryabinkin, Alexander G. Kvashnin, Milad Asgarpour, И. И. Маслеников, D. A. Ovsyannikov, Павел Б. Сорокин, Mikhail Popov, Alexander V. Shapeev

2022Journal of Chemical Theory and Computation26 citationsDOI

Abstract

We propose a methodology for the calculation of nanohardness by atomistic simulations of nanoindentation. The methodology is enabled by machine-learning interatomic potentials fitted on the fly to quantum-mechanical calculations of local fragments of the large nanoindentation simulation. We test our methodology by calculating nanohardness, as a function of load and crystallographic orientation of the surface, of diamond, AlN, SiC, BC2N, and Si and comparing it to the calibrated values of the macro- and microhardness. The observed agreement between the computational and experimental results from the literature provides evidence that our method has sufficient predictive power to open up the possibility of designing materials with exceptional hardness directly from first principles. It will be especially valuable at the nanoscale where the experimental measurements are difficult, while empirical models fitted to macrohardness are, as a rule, inapplicable.

Topics & Concepts

NanoindentationDiamondIndentation hardnessMaterials scienceMacroOrientation (vector space)Function (biology)Nanoscopic scaleComputer scienceNanotechnologyComposite materialMicrostructureMathematicsGeometryEvolutionary biologyBiologyProgramming languageMetal and Thin Film MechanicsDiamond and Carbon-based Materials ResearchAdvanced materials and composites
Nanohardness from First Principles with Active Learning on Atomic Environments | Litcius