The Tin Pest Problem as a Test of Density Functionals Using High-Throughput Calculations
Abstract
At ambient pressure tin transforms from its ground-state semi-metal -Sn (diamond structure) phase to the compact metallic -Sn phase at 13C (286K). There may be a further transition to the simple hexagonal -Sn above 450K. These relatively low transition temperatures are due to the small energy differences between the structures, \,meV/atom between - and -Sn. This makes tin an exceptionally sensitive test of the accuracy of density functionals and computational methods. Here we use the high-throughput Automatic-FLOW (AFLOW) method to study the energetics of tin in multiple structures using a variety of density functionals. We look at the successes and deficiencies of each functional. As no functional is completely satisfactory, we look Hubbard U corrections and show that the Coulomb interaction can be chosen to predict the correct phase transition temperature. We also discuss the necessity of testing high-throughput calculations for convergence for systems with small energy differences.
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Cite
@article{arxiv.2010.07168,
title = {The Tin Pest Problem as a Test of Density Functionals Using High-Throughput Calculations},
author = {Michael J. Mehl and Mateo Ronquillo and David Hicks and Marco Esters and Corey Oses and Rico Friedrich and Andriy Smolyanyuk and Eric Gossett and Daniel Finkenstadt and Stefano Curtarolo},
journal= {arXiv preprint arXiv:2010.07168},
year = {2021}
}
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17 pages