Accurate representation of formation energies of crystalline alloys with many components

Shapeev, Alexander V.

doi:10.1016/j.commatsci.2017.07.010

Cited by 50 publications

(36 citation statements)

References 25 publications

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“…This is just one of a class of recently popularized machine learning methods for creating nonparametric interatomic potentials, which has been shown to be very successful in tackling difficult materials modelling problems, ranging from investigating the structure of amorphous materials (carbon (Deringer et al, 2017(Deringer et al, , 2019, silicon (Bartók et al, 2018)), the mechanics of metals (tungsten (Szlachta et al, 2014), iron (Dragoni et al, 2018)) to molecular liquids such (water (Bartók et al, 2013a), methane (Veit et al, 2019). There are many alternatives, using other regression frameworks, such as artificial neural networks (Behler and Parrinello, 2007) and even linear regression (Shapeev, 2017;Drautz, 2019). All these methods are improvable, since using more input data typically leads to more accurate potentials, due to the nonparametric nature of the functional forms.…”

Section: Machine Learning Potentialsmentioning

confidence: 99%

Partitioning of sulfur between solid and liquid iron under Earth’s core conditions: Constraints from atomistic simulations with machine learning potentials

Zhang

Csänyi

2020

Geochimica et Cosmochimica Acta

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Partition coefficients of light elements between the solid and liquid iron phases are crucial for uncovering the state and dynamics of the Earth's core. As one of the major light element candidates, sulfur has attracted extensive interests for measuring its partitioning and phase behaviors over the last several decades, but the relevant experimental data under Earth's core conditions are still scarce. In this study, using a toolkit consisting of electronic structure theory, high-accuracy machine learning potentials and rigorous free energy calculations, we establish an efficient and extendible framework for predicting complex phase behaviors of iron alloys under extreme conditions. As a first application of this framework, we predict the partition coefficients of sulfur over wide range of temperatures and pressures (from 4000 K, 150 GPa to 6000 K, 330 GPa), which are demonstrated to be in good agreement with previous experiments and ab initio simulations. After a continuous increase below ~250 GPa, the partition coefficient is found to be around 0.750.07 at higher pressures and are essentially temperature-independent. Given these predictions, the partitioning of sulfur is confirmed to be insufficient to account for the observed density jump across the Earth's inner core boundary and its roles on the geodynamics of the Earth's core should be minor.

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Section: Machine Learning Potentialsmentioning

confidence: 99%

Partitioning of sulfur between solid and liquid iron under Earth’s core conditions: Constraints from atomistic simulations with machine learning potentials

Zhang

Csänyi

2020

Geochimica et Cosmochimica Acta

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“…In the on-lattice model, LRP, 18 the energy of each configuration is partitioned into contributions of the separate atomic environments of each atom as…”

Section: Interatomic Potentialmentioning

confidence: 99%

Impact of lattice relaxations on phase transitions in a high-entropy alloy studied by machine-learning potentials

et al. 2019

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Recently, high-entropy alloys (HEAs) have attracted wide attention due to their extraordinary materials properties. A main challenge in identifying new HEAs is the lack of efficient approaches for exploring their huge compositional space. Ab initio calculations have emerged as a powerful approach that complements experiment. However, for multicomponent alloys existing approaches suffer from the chemical complexity involved. In this work we propose a method for studying HEAs computationally. Our approach is based on the application of machine-learning potentials based on ab initio data in combination with Monte Carlo simulations. The high efficiency and performance of the approach are demonstrated on the prototype bcc NbMoTaW HEA. The approach is employed to study phase stability, phase transitions, and chemical short-range order. The importance of including local relaxation effects is revealed: they significantly stabilize single-phase formation of bcc NbMoTaW down to room temperature. Finally, a so-far unknown mechanism that drives chemical order due to atomic relaxation at ambient temperatures is discovered.npj Computational Materials (2019) 5:55 ; https://doi.

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“…Для моделирования эволюции атомной структуры необходимо описывать зависимость энергии системы от конфигурации атомных окружений. В данной работе для этой цели использовался малоранговый потенциал межатомного взаимодействия на решетке (выше был обозначен LRP) [48]. LRP относится к классу машиннообучаемых потенциалов, его основной задачей является интерполяция результатов квантово-механических расчетов.…”

Section: малоранговый потенциал взаимодействияunclassified

“…Использование облучения для ускорения диффузионных процессов позволяет детектировать структурные изменения при более низкихтемпературах [46,47]. Теоретическая часть исследования проводится с помощью атомистического Монте-Карло с использованием потенциала [48].…”

Section: Introductionunclassified

Экспериментально-теоретическое исследование эволюции атомной структуры высокоэнтропийных сплавов на основе Fe, Cr, Ni, Mn и Co при термическом и радиационном старении

Мешков¹,

Новоселов²,

Янилкин³

et al. 2020

Физика Твердого Тела

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The comprehensive experimental and theoretical study of the processes of local ordering of multicomponent alloys was carried out. Experimental techniques included atom-probe tomography and measurement of electrical resistivity during isochronal annealing. The theoretical study was carried out by atomistic modeling methods. The evolution of the system was described in the framework of the multiscale paradigm which is based on quantum-mechanical calculations. The initial stage of the decomposition of a solid solution of CoCrFeNi alloy with the formation of Ni4Cr and Ni2Cr precipitations was demonstrated for the first time by the employed approach.

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Accurate representation of formation energies of crystalline alloys with many components

Cited by 50 publications

References 25 publications

Partitioning of sulfur between solid and liquid iron under Earth’s core conditions: Constraints from atomistic simulations with machine learning potentials

Partitioning of sulfur between solid and liquid iron under Earth’s core conditions: Constraints from atomistic simulations with machine learning potentials

Impact of lattice relaxations on phase transitions in a high-entropy alloy studied by machine-learning potentials

Экспериментально-теоретическое исследование эволюции атомной структуры высокоэнтропийных сплавов на основе Fe, Cr, Ni, Mn и Co при термическом и радиационном старении

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