Predicted alternative structure for tantalum metal under high pressure and high temperature

Liu, Zhongli; Cai, Ling-Cang; Zhang, Xiu-Lu; Xing, Feng

doi:10.1063/1.4818963

Cited by 11 publications

(16 citation statements)

References 47 publications

(79 reference statements)

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“…Furthermore, the MGPT-MD simulations directly showed that hex-ω exhibits poor mechanical stability and partial transformation to bcc, suggesting that it would actually be mechanically unstable at all temperatures and pressures in an unconstrained environment. The mechanical instability of hex-ω has since been so confirmed with first-principles, finite-temperature latticedynamics calculations [17,18]. Thus, of the structures studied in Refs.…”

Section: A(ωt ) = A(ω Ref T ) − P( ′ ωmentioning

confidence: 65%

“…12 as well as to the orthorhombic Pnma phase suggested by Yao and Klug [17] and by Liu et al [18]. In addition to treatment with MGPT potentials, the present free-energy method can also be adapted to other temperature-independent potentials, including GPT, BOP, EAM, and FS potentials among others, for suitable applications in relevant materials.…”

Section: F Metastable Fcc Free Energymentioning

confidence: 99%

“…12 and 16, only A15, fcc and hcp remain as candidate metastable phases for our RSMD free-energy method. To that list additional candidate structures may be added in the future, including the orthorhombic Pnma structure, which recently has been predicted to be mechanically stable in Ta over wide ranges of temperature and pressure [17,18].…”

Section: A(ωt ) = A(ω Ref T ) − P( ′ ωmentioning

confidence: 99%

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Efficient wide-range calculation of free energies in solids and liquids using reversible-scaling molecular dynamics

Moriarty

Haskins

2014

Phys. Rev. B

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We elaborate a novel and efficient method to obtain multiphase Helmholtz free energies from molecular dynamics (MD) simulations over wide ranges of volume and temperature in materials that can be described by temperature-independent ion forces, with both higher accuracy and order-of-magnitude cost savings compared to direct thermodynamicintegration techniques. Our method leverages and significantly extends the technique of reversible scaling molecular dynamics (RSMD) proposed by de Koning et al. [Phys. Rev. Lett. 83, 3973 (1999)], which allows a free-energy difference in a given phase at constant volume to be calculated as a function of temperature from a single MD simulation. In mechanically stable solid phases, our approach carefully combines quasiharmonic lattice dynamics at low temperatures with an accurate and fully isolated RSMD simulation of the anharmonic vibrational free energy at high temperatures to produce a seamless free energy from zero temperature to above melt along constant-volume isochores. In the liquid, we combine a unique calculation of the free energy along a high-temperature reference isotherm with isochoric RSMD simulations from that temperature to below melt. In metastable solid phases that are mechanically unstable at low temperature, we use two-phase MD melt simulations together with the liquid free energy to obtain the solid free energy along the solidus melt line and then perform isochoric RSMD simulations to temperatures above and below that point. While our free-energy method is general, we have specifically adapted it here to the case of metals in which the ion forces are well described by model generalized pseudopotential theory (MGPT) multi-ion interatomic potentials, and additive electron-thermal free-energy contributions can be 2 included. Then using refined Ta6.8x MGPT potentials, we have converged total free energies and their components to very high and unprecedented sub−milli-Rydberg (mRy) numerical accuracy in the stable-bcc, liquid, and metastable-fcc phases of tantalum for volumes ranging from up to 26% expansion to nearly two-fold compression and for temperatures to 25,000 K. In turn, we have successfully used the free energies so obtained to calculate physically accurate thermodynamic properties and gain new insight into their behavior, including sensitive thermodynamic derivatives, bcc and fcc melt curves, and a multiphase equation of state for Ta over the same temperature range and for pressures as high as 600 GPa. We show that the anharmonic free-energy component in the bcc solid, although only 1-5 mRy in magnitude for Ta, can have a significant (15-20%) effect on thermal expansivity, the Grüneisen parameter, and melt temperatures. We further show that the electron-thermal free-energy component can similarly impact the specific heat and thermal expansivity in both the solid and the liquid, while only minimally affecting (to ≤ 3%) the bcc and fcc melt curves.

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Section: A(ωt ) = A(ω Ref T ) − P( ′ ωmentioning

confidence: 65%

Section: F Metastable Fcc Free Energymentioning

confidence: 99%

Section: A(ωt ) = A(ω Ref T ) − P( ′ ωmentioning

confidence: 99%

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Efficient wide-range calculation of free energies in solids and liquids using reversible-scaling molecular dynamics

Moriarty

Haskins

2014

Phys. Rev. B

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“…The melting points are obtained by pursuing the steady solid-liquid coexistence phase. 24) at high pressure and high temperature is controversial, bcc phase has been proved to be the most stable phase at T ¼ 0 up to 300 GPa. In molecular dynamics simulation, it is really a hard work to choose a proper potential to describe the phase relation of Ta.…”

Section: Equilibrium Melting Temperaturementioning

confidence: 99%

“…On one hand, whether or not a solid-solid phase transition occurred before melting is a hot topic. Several possible phases, i.e., hex-x, [18][19][20][21] A15, 22,23 and pnma, 24 have been reported to be the possible competitive phases with bodycentered cubic (bcc) at high pressure and high temperature. However, no agreement has been reached among them at the moment.…”

Section: Introductionmentioning

confidence: 99%

Melting curves and structural properties of tantalum from the modified-Z method

Liu

Cheng

et al. 2015

Journal of Applied Physics

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The melting curves and structural properties of tantalum (Ta) are investigated by molecular dynamics simulations combining with potential model developed by Ravelo et al. [Phys. Rev. B 88, 134101 (2013)]. Before calculations, five potentials are systematically compared with their abilities of producing reasonable compressional and equilibrium mechanical properties of Ta. We have improved the modified-Z method introduced by Wang et al. [J. Appl. Phys. 114, 163514 (2013)] by increasing the sizes in L x and L y of the rectangular parallelepiped box (L x ¼ L y (L z). The influences of size and aspect ratio of the simulation box to melting curves are also fully tested. The structural differences between solid and liquid are detected by number density and local-order parameters Q 6. Moreover, the atoms' diffusion with simulation time, defects, and vacancies formations in the sample are all studied by comparing situations in solid, solid-liquid coexistence, and liquid state. V

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High-pressure phase diagram of gold from first-principles calculations: Converging to an isotropic atomic stacking order

Liu

Tao

Zhang

et al. 2016

Computational Materials Science

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Predicted alternative structure for tantalum metal under high pressure and high temperature

Cited by 11 publications

References 47 publications

Efficient wide-range calculation of free energies in solids and liquids using reversible-scaling molecular dynamics

Efficient wide-range calculation of free energies in solids and liquids using reversible-scaling molecular dynamics

Melting curves and structural properties of tantalum from the modified-Z method

High-pressure phase diagram of gold from first-principles calculations: Converging to an isotropic atomic stacking order

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