First-principles calculation of self-diffusion coefficients

M. Mantina; Y. Wang; R. Arroyave; L. Q. Chen; Zi Kui Liu; C. Wolverton

First-principles calculation of self-diffusion coefficients

M. Mantina
, Y. Wang
, R. Arroyave
, L. Q. Chen
, Zi Kui Liu
, C. Wolverton

Materials Science and Engineering

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

We demonstrate a first-principles method to compute all factors entering the vacancy-mediated self-diffusion coefficient. Using density functional theory calculations of fcc Al as an illustrative case, we determine the energetic and entropic contributions to vacancy formation and atomic migration. These results yield a quantitative description of the migration energy and vibrational prefactor via transition state theory. The calculated diffusion parameters and coefficients show remarkably good agreement with experiments. We provide a simple physical picture for the positive entropic contributions.

Original language	English (US)
Title of host publication	Zentropy
Subtitle of host publication	Tools, Modelling, and Applications
Publisher	Jenny Stanford Publishing
Pages	165-175
Number of pages	11
ISBN (Electronic)	9781040118566
ISBN (Print)	9789815129441
State	Published - Aug 23 2024

All Science Journal Classification (ASJC) codes

General Engineering
General Physics and Astronomy
General Chemistry
General Agricultural and Biological Sciences
General Biochemistry, Genetics and Molecular Biology
General Medicine
General Chemical Engineering

Cite this

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title = "First-principles calculation of self-diffusion coefficients",

abstract = "We demonstrate a first-principles method to compute all factors entering the vacancy-mediated self-diffusion coefficient. Using density functional theory calculations of fcc Al as an illustrative case, we determine the energetic and entropic contributions to vacancy formation and atomic migration. These results yield a quantitative description of the migration energy and vibrational prefactor via transition state theory. The calculated diffusion parameters and coefficients show remarkably good agreement with experiments. We provide a simple physical picture for the positive entropic contributions.",

author = "M. Mantina and Y. Wang and R. Arroyave and Chen, \{L. Q.\} and Liu, \{Zi Kui\} and C. Wolverton",

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T1 - First-principles calculation of self-diffusion coefficients

AU - Mantina, M.

AU - Wang, Y.

AU - Arroyave, R.

AU - Chen, L. Q.

AU - Liu, Zi Kui

AU - Wolverton, C.

PY - 2024/8/23

Y1 - 2024/8/23

N2 - We demonstrate a first-principles method to compute all factors entering the vacancy-mediated self-diffusion coefficient. Using density functional theory calculations of fcc Al as an illustrative case, we determine the energetic and entropic contributions to vacancy formation and atomic migration. These results yield a quantitative description of the migration energy and vibrational prefactor via transition state theory. The calculated diffusion parameters and coefficients show remarkably good agreement with experiments. We provide a simple physical picture for the positive entropic contributions.

AB - We demonstrate a first-principles method to compute all factors entering the vacancy-mediated self-diffusion coefficient. Using density functional theory calculations of fcc Al as an illustrative case, we determine the energetic and entropic contributions to vacancy formation and atomic migration. These results yield a quantitative description of the migration energy and vibrational prefactor via transition state theory. The calculated diffusion parameters and coefficients show remarkably good agreement with experiments. We provide a simple physical picture for the positive entropic contributions.

UR - https://www.scopus.com/pages/publications/85201253494

UR - https://www.scopus.com/pages/publications/85201253494#tab=citedBy

M3 - Chapter

AN - SCOPUS:85201253494

SN - 9789815129441

SP - 165

EP - 175

BT - Zentropy

PB - Jenny Stanford Publishing

ER -

First-principles calculation of self-diffusion coefficients

Abstract

All Science Journal Classification (ASJC) codes

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