Random phase approximation up to the melting point: Impact of anharmonicity and nonlocal many-body effects on the thermodynamics of Au

Grabowski, Blazej; Wippermann, Stefan Martin; Glensk, Albert; Hickel, Tilmann; Neugebauer, Jörg

doi:10.1103/physrevb.91.201103

Cited by 18 publications

(16 citation statements)

References 26 publications

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“…The same behavior has been reported previously for Au [35], where the heat capacity calculated within the quasiharmonic approximation diverged in a similar manner for the GGA results. In that work it was found that the inclusion of anharmonic contributions only partially corrected this unphysical divergence, which could be fully removed by including a treatment of exchange and correlation within the random phase approximation (RPA).…”

Section: B Resultssupporting

confidence: 88%

Improved method of calculatingab initiohigh-temperature thermodynamic properties with application to ZrC

Duff¹,

Davey²,

Korbmacher

et al. 2015

Phys. Rev. B

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Thermodynamic properties of ZrC are calculated up to the melting point (T melt ≈ 3700 K), using density functional theory (DFT) to obtain the fully anharmonic vibrational contribution, and including electronic excitations. A significant improvement is found in comparison to results calculated within the quasiharmonic approximation. The calculated thermal expansion is in better agreement with experiment and the heat capacity reproduces rather closely a CALPHAD estimate. The calculations are presented as an application of a development of the upsampled thermodynamic integration using Langevin dynamics (UP-TILD) approach. This development, referred to here as two-stage upsampled thermodynamic integration using Langevin dynamics (TU-TILD), is the inclusion of tailored interatomic potentials to characterize an intermediate reference state of anharmonic vibrations on a two-stage path of thermodynamic integration between the original DFT quasiharmonic free energy and the fully anharmonic DFT free energy. This approach greatly accelerates the convergence of the calculation, giving a factor of improvement in efficiency of ∼50 in the present case compared to the original UP-TILD approach, and it can be applied to a wide range of materials.

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Section: B Resultssupporting

confidence: 88%

Improved method of calculatingab initiohigh-temperature thermodynamic properties with application to ZrC

Duff¹,

Davey²,

Korbmacher

et al. 2015

Phys. Rev. B

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“…There are a number of approaches in the literature to calculate the anharmonic vibrational properties of crystals, [1][2][3][4][12][13][14][15][16][17][18][19][20][21][22] including thermodynamic integration 23 (TI), which is the method used in this work. In TI the anharmonic part of the full Hamiltonian, E − E qh , is switched on with the parameter λ ∈ [0, 1], in this instance linearly as E mix (λ) = E qh + λ(E − E qh ).…”

Section: A Backgroundmentioning

confidence: 99%

Fast anharmonic free energy method with an application to vacancies in ZrC

et al. 2019

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We propose an approach to calculate the anharmonic part of the volumetric-strain and temperature dependent free energy of a crystal. The method strikes an effective balance between accuracy and computational efficiency, showing a ×10 speed-up on comparable free energy approaches at the level of density functional theory, with average errors less than 1 meV/atom. As a demonstration we make new predictions on the thermodynamics of substoichiometric ZrCx, including vacancy concentration and heat capacity.

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“…As discussed above, the inclusion of magnetic excitations and their impact on vibrational properties for magnetic materials such as CrN is crucial. Advancements beyond the above described approximations are being developed, for example, to treat defected and/or disordered systems (e.g., to account at elevated temperatures for thermodynamically driven creation of vacancies [126,144,157] or temperature-driven partitioning of substitutionally alloyed steels [158] ), the delicate interplay between various magnetic excitations (e.g., longitudinal spin fluctuations) and lattice vibrations (e.g., explicit anharmonic contributions) [135,136] or for predictions in multi-component systems, such as the new class of high entropy alloys. [45] Taking the magnetic contributions properly into account, the standard GGA approximation yielded T N ¼ 428K.…”

Section: Ab Initio Thermodynamicsmentioning

confidence: 99%

“…[38] These results demonstrate the predictive power of current theoretical approaches, which can be applied to many systems of practical interest, in particular in light of the nowadays available and ongoing increasing computational power. Advancements beyond the above described approximations are being developed, for example, to treat defected and/or disordered systems (e.g., to account at elevated temperatures for thermodynamically driven creation of vacancies [126,144,157] or temperature-driven partitioning of substitutionally alloyed steels [158] ), the delicate interplay between various magnetic excitations (e.g., longitudinal spin fluctuations) and lattice vibrations (e.g., explicit anharmonic contributions) [135,136] or for predictions in multi-component systems, such as the new class of high entropy alloys. [140,141,159,160] An important application field for "ab initio" thermodynamic data is using them as input for the CALPHAD method [161][162][163][164][165][166] implemented in simulation packages, such as Thermocalc [167] and Matcalc.…”

Section: Ab Initio Thermodynamicsmentioning

confidence: 99%

Atomistic Modeling‐Based Design of Novel Materials

Holec¹,

Zhou

Riedl

et al. 2017

Adv Eng Mater

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Modern materials science increasingly advances via a knowledge-based development rather than a trialand-error procedure. Gathering large amounts of data and getting deep understanding of non-trivial relationships between synthesis of materials, their structure and properties is experimentally a tedious work. Here, theoretical modeling plays a vital role. In this review paper we briefly introduce modeling approaches employed in materials science, their principles and fields of application. We then focus on atomistic modeling methods, mostly quantum mechanical ones but also Monte Carlo and classical molecular dynamics, to demonstrate their practical use on selected examples. of the Deutsche Forschungsgemeinschaft (DFG). D.M. acknowledges the Collaborative Research Center SFB-TR 87/2 "Pulsed high power plasmas for the synthesis of nanostructured functional layers" of the DFG. The computational results presented have been achieved in part using the Vienna Scientific Cluster (VSC).

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Random phase approximation up to the melting point: Impact of anharmonicity and nonlocal many-body effects on the thermodynamics of Au

Cited by 18 publications

References 26 publications

Improved method of calculatingab initiohigh-temperature thermodynamic properties with application to ZrC

Improved method of calculatingab initiohigh-temperature thermodynamic properties with application to ZrC

Fast anharmonic free energy method with an application to vacancies in ZrC

Atomistic Modeling‐Based Design of Novel Materials

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