Litcius/Paper detail

Elinvar effect in β-Ti simulated by on-the-fly trained moment tensor potential

Alexander V Shapeev, Evgeny V Podryabinkin, Konstantin Gubaev, Ferenc Tasnádi, Igor A Abrikosov

2020New Journal of Physics37 citationsDOIOpen Access PDF

Abstract

Abstract A combination of quantum mechanics calculations with machine learning techniques can lead to a paradigm shift in our ability to predict materials properties from first principles. Here we show that on-the-fly training of an interatomic potential described through moment tensors provides the same accuracy as state-of-the-art ab initio molecular dynamics in predicting high-temperature elastic properties of materials with two orders of magnitude less computational effort. Using the technique, we investigate high-temperature bcc phase of titanium and predict very weak, Elinvar, temperature dependence of its elastic moduli, similar to the behavior of the so-called GUM Ti-based alloys (Sato et al 2003 Science 300 464). Given the fact that GUM alloys have complex chemical compositions and operate at room temperature, Elinvar properties of elemental bcc-Ti observed in the wide temperature interval 1100–1700 K is unique.

Topics & Concepts

PhysicsInteratomic potentialMoment (physics)Molecular dynamicsTensor (intrinsic definition)Phase (matter)Interval (graph theory)Statistical physicsTitanium alloyCondensed matter physicsTitaniumQuantumThermodynamicsPhase transitionAb initio quantum chemistry methodsMoleculePotential methodMoment tensorSecond moment of areaQuantum mechanicsClassical mechanicsMachine Learning in Materials ScienceTitanium Alloys Microstructure and PropertiesAdvanced Electron Microscopy Techniques and Applications