High-throughput prediction of finite-temperature properties using the quasi-harmonic approximation

Demet Usanmaz; Pinku Nath; Jose J. Plata; Rabih Al Rahal Al Orabi; Marco Fornari; Marco Buongiorno Nardelli; Cormac Toher; Stefano Curtarolo

doi:10.1016/j.commatsci.2016.07.043

High-throughput prediction of finite-temperature properties using the quasi-harmonic approximation

Demet Usanmaz, Pinku Nath, Jose J. Plata, Rabih Al Rahal Al Orabi, Marco Fornari, Marco Buongiorno Nardelli, Cormac Toher, Stefano Curtarolo

Kettering University

Research output: Contribution to journal › Article › peer-review

Abstract

In order to calculate thermal properties in automatic fashion, the Quasi-Harmonic Approximation (QHA) has been combined with the Automatic Phonon Library (APL) and implemented within the AFLOW framework for high-throughput computational materials science. As a benchmark test to address the accuracy of the method and implementation, the specific heats capacities, thermal expansion coefficients, Grüneisen parameters and bulk moduli have been calculated for 130 compounds. It is found that QHA-APL can reliably predict such values for several different classes of solids with root mean square relative deviation smaller than 28% with respect to experimental values. The automation, robustness, accuracy and precision of QHA-APL enable the computation of large material data sets, the implementation of repositories containing thermal properties, and finally can serve the community for data mining and machine learning studies

Original language	American English
Journal	Computational Materials Science
Volume	125
DOIs	https://doi.org/10.1016/j.commatsci.2016.07.043
State	Published - Dec 2016

Keywords

High-throughput
materials genomics
Quasi-Harmonic Approximation
AFLOW

Disciplines

Physical Sciences and Mathematics
Physics

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Cite this

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title = "High-throughput prediction of finite-temperature properties using the quasi-harmonic approximation",

abstract = " In order to calculate thermal properties in automatic fashion, the Quasi-Harmonic Approximation (QHA) has been combined with the Automatic Phonon Library (APL) and implemented within the AFLOW framework for high-throughput computational materials science. As a benchmark test to address the accuracy of the method and implementation, the specific heats capacities, thermal expansion coefficients, Gr{\"u}neisen parameters and bulk moduli have been calculated for 130 compounds. It is found that QHA-APL can reliably predict such values for several different classes of solids with root mean square relative deviation smaller than 28% with respect to experimental values. The automation, robustness, accuracy and precision of QHA-APL enable the computation of large material data sets, the implementation of repositories containing thermal properties, and finally can serve the community for data mining and machine learning studies",

keywords = "High-throughput, materials genomics, Quasi-Harmonic Approximation, AFLOW",

author = "Demet Usanmaz and Pinku Nath and Plata, {Jose J.} and {Al Rahal Al Orabi}, Rabih and Marco Fornari and {Buongiorno Nardelli}, Marco and Cormac Toher and Stefano Curtarolo",

year = "2016",

month = dec,

doi = "10.1016/j.commatsci.2016.07.043",

language = "American English",

volume = "125",

journal = "Computational Materials Science",

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T1 - High-throughput prediction of finite-temperature properties using the quasi-harmonic approximation

AU - Usanmaz, Demet

AU - Nath, Pinku

AU - Plata, Jose J.

AU - Al Rahal Al Orabi, Rabih

AU - Fornari, Marco

AU - Buongiorno Nardelli, Marco

AU - Toher, Cormac

AU - Curtarolo, Stefano

PY - 2016/12

Y1 - 2016/12

N2 - In order to calculate thermal properties in automatic fashion, the Quasi-Harmonic Approximation (QHA) has been combined with the Automatic Phonon Library (APL) and implemented within the AFLOW framework for high-throughput computational materials science. As a benchmark test to address the accuracy of the method and implementation, the specific heats capacities, thermal expansion coefficients, Grüneisen parameters and bulk moduli have been calculated for 130 compounds. It is found that QHA-APL can reliably predict such values for several different classes of solids with root mean square relative deviation smaller than 28% with respect to experimental values. The automation, robustness, accuracy and precision of QHA-APL enable the computation of large material data sets, the implementation of repositories containing thermal properties, and finally can serve the community for data mining and machine learning studies

AB - In order to calculate thermal properties in automatic fashion, the Quasi-Harmonic Approximation (QHA) has been combined with the Automatic Phonon Library (APL) and implemented within the AFLOW framework for high-throughput computational materials science. As a benchmark test to address the accuracy of the method and implementation, the specific heats capacities, thermal expansion coefficients, Grüneisen parameters and bulk moduli have been calculated for 130 compounds. It is found that QHA-APL can reliably predict such values for several different classes of solids with root mean square relative deviation smaller than 28% with respect to experimental values. The automation, robustness, accuracy and precision of QHA-APL enable the computation of large material data sets, the implementation of repositories containing thermal properties, and finally can serve the community for data mining and machine learning studies

KW - High-throughput

KW - materials genomics

KW - Quasi-Harmonic Approximation

KW - AFLOW

U2 - 10.1016/j.commatsci.2016.07.043

DO - 10.1016/j.commatsci.2016.07.043

M3 - Article

VL - 125

JO - Computational Materials Science

JF - Computational Materials Science

ER -