Molecular dynamics simulations of the melting curve of NiAl alloy under pressure

Zhang, Wenjin; Peng, Yufeng; Liu, Zhongli

doi:10.1063/1.4876515

Cited by 24 publications

(17 citation statements)

References 58 publications

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“…Generally, evaluating the melting point is not a straightforward approach because it requires the calculation of Gibbs free energies, which is a multistage process that needs several different molecular dynamics simulations. In case of B2 NiAl alloy many studies have conducted to find its melting point under various pressure, however the results are significant different between these research groups [1,2,4]. The discrepancies may come from different method and potential applied.…”

Section: Introductionmentioning

confidence: 89%

“…The discrepancies may come from different method and potential applied. Even in the simplest case when pressure equal zero, there are two different experiment values of B2 NiAl melting point 1911 K and 1995 K were reported from literature [2,4,8]. The authors of this work would like to provide another perspective to this classical problem in thermodynamics.…”

Section: Introductionmentioning

confidence: 99%

“…This method is empirical, which based on the classical nucleation theory [2]. In this method, there is a sudden change in volume (potential energy) when solid is heating at superheating temperature T sh far beyond the melting temperature T m , and when liquid is cooling at supercooling temperature T sc far below T m .…”

Section: Calculation Of Melting Pointmentioning

confidence: 99%

“…The volumetemperature V-T (or potential energy-temperature) curve show the hysteresis effect of heating solid and cooling liquid. The melting point T m can be estimated from T sh and T sc by the following formula [2,7,11] .…”

Section: Calculation Of Melting Pointmentioning

confidence: 99%

“…Among these structures, B2 (CsCl-type, Pm3m space group) is the most stable one both at ambient and very high pressure at room temperature [2]. The B2 NiAl compound is of particular interest from a mechanical point of view that motivate its extensive use in industry [3].…”

Section: Introductionmentioning

confidence: 99%

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Molecular Dynamics Studies of B2 NiAl Alloy Melting Point

N.T.H.

H.S.M.

Starostenkov

2017

izvasu

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1Алтайский государственный технический университет им. И.И. Ползунова (Барнаул, Россия) 2 Институт ядерных исследований (Далат, Вьетнам) In this paper, we perform a computer simulation to investigate the melting point at zero pressure of B2 NiAl intermetallic alloy by using LAMMPS with EAM potential developed by Mishin et al. Simulation box contains 20×20×20 unit cells with 16000 atoms, periodic boundary conditions are applied in three directions. To verify the quality of Mishin potential we first conduct several simulations to calculate defects formation energy, cohesive energy, equilibrium lattice constant and elastic constants of this alloy at absolute zero. The main simulation is performed by using one-phase method in NPT ensemble. Simulation results are analyzed and visualized by Ovito using radical distribution function and common neighbor analysis method. We observe B2 NiAl bulk alloy that begins to melt at 1840 K and crystallizes at 1153 K with critical cooling rate higher than those of almost other alloys. The good agreement between simulation results and experiment suggests that we should continue using Mishin potential for further work in B2 NiAl case study with more sophisticate simulation.Key word: molecular dynamics, lammps, eam potential, one-phase method, melting point, phase transition, critical cooling rate, crystallization, time-temperature-transformation diagram.Применено компьютерное моделирование для ис-следования точки плавления при нулевом давлении интерметаллида NiAl со сверхструктурой В2 с исполь-зованием Lammps программного комплекса с потен-циалом взаимодействия атомов, полученного по ме-тоду погруженного атома в работе Y. Mishin и др. Рассчитанный блок кристалла содержал 20x20x20 эле-ментарных ячеек, включающих 16000 атомов, к грани-цам расчетного блока прикладывались периодические граничные условия в трех направлениях. Для верифи-кации качества потенциала Y. Mishin и других были выполнены компьютерные эксперименты по вычисле-нию энергий образования точечных дефектов, энергии когезии, равновесного параметра решетки и упругих констант сплава NiAl при абсолютном нуле. Основная процедура моделирования была проведена по мето-ду однофазного PVT ансамбля. Результаты модели-рования были проанализированы и визуализирова-ны с использованием программного комплекса Ovito и с функции радиального распределения и анализа общего числа соседей атомов. Исследовался интер-металлид NiAl сверхструктуры В2 в объеме начиная с температуры плавления 1840 К и возникновения кристаллизации при температуре 1153 К с высокой скоростью охлаждения. Хорошее согласие резуль-татов моделирования и экспериментальных данных подтверждает возможность применения потенциала Y. Mishin и других для дальнейших работ по иссле-дованию сплава NiAl сверхструктуры В2.Ключевые слова: молекулярная динамика, lammps, ме-тод потенциала погруженного атома, точка плавления, фазовый переход, критическая скорость охлаждения, диаграмма температурно-временной трансформации.

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Section: Introductionmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Calculation Of Melting Pointmentioning

confidence: 99%

Section: Calculation Of Melting Pointmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Molecular Dynamics Studies of B2 NiAl Alloy Melting Point

N.T.H.

H.S.M.

Starostenkov

2017

izvasu

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SHS in Ni/Al Nanofoils: A Review of Experiments and Molecular Dynamics Simulations

et al. 2018

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Non-isothermal processes in nanometric metallic multilayers are reviewed, both experimentally and theoretically. The Ni/Al nanofoil is considered as a model system. On the one hand, the experimental methods of elaboration and analysis are presented and, on the other hand, the modeling approach at the macroscopic and atomic scale. The basic experimental features are reported together with recent achievements. Molecular dynamics investigation of the reactivity of Ni/Al systems is reported for bulk systems and nanosystems including nanoparticles, nanowires, nanofilms, and multilayers. The focus is on atomic-scale modeling versus experiments. Molecular dynamics approaches allow us to elucidate the mechanisms of nonisothermal processes occurring in nanoscale systems, such as phase transformations and self-propagation reactions.

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Computational Search for Compounds with the Highest Melting Temperature in the Ternary HfC‐Based Ceramics

Peng,

Tikhonov

2024

Physica Status Solidi (b)

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The melting temperature (Tm) determines the service temperature of ultrahigh‐temperature ceramics (UHTCs), so it is of great significance to search for compound with the highest Tm in UHTCs. In present work, the formula to calculate the Tm of UHTCs with the rock salt structure is modified first: Tm = f(c)EVm/(100kB), f(c) = 0.6412*c + 0.9947, which considers the influence of vacancy concentration (c) on the Tm. The calculated Tms are in good agreement with the experimental values of UHTCs, and the calculation accuracy exceeds 91%. The Tm could be obtained by only calculating the elastic modulus and volume per atom. Using this formula, the Tms of ternary HfC‐based UHTCs with the rock salt structure are predicted, and a new compound with the highest melting temperature, HfTa2C3, is found. Finally, the empirical relationship between the Tm and shear modulus or Vickers hardness of UHTCs with the rock salt structure is also investigated.

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Molecular dynamics simulations of the melting curve of NiAl alloy under pressure

Cited by 24 publications

References 58 publications

Molecular Dynamics Studies of B2 NiAl Alloy Melting Point

Molecular Dynamics Studies of B2 NiAl Alloy Melting Point

SHS in Ni/Al Nanofoils: A Review of Experiments and Molecular Dynamics Simulations

Computational Search for Compounds with the Highest Melting Temperature in the Ternary HfC‐Based Ceramics

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