BiInO.sub.3 phases under asymmetric in-plane strain

Density functional theory is used to study the effect of asymmetric in-plane strain on various BiInO.sub.3 phases. Structural relaxation is carried out to simulate the growth of coherently strained epitaxial films on (001) oriented orthorhombic perovskite substrates. The results are in particular an...

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Veröffentlicht in:	Journal of materials science 2021-05, Vol.56 (14), p.8406
Hauptverfasser:	Herklotz, Andreas, Tippey, Kristin, Huon, Amanda, Koch, Martin M, Dörr, Kathrin, Herklotz, Frank
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Sprache:	eng
Schlagworte:	Analysis Density functionals Dielectric films Epitaxy Perovskite Pyroxene Thin films
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creator	Herklotz, Andreas Tippey, Kristin Huon, Amanda Koch, Martin M Dörr, Kathrin Herklotz, Frank
description	Density functional theory is used to study the effect of asymmetric in-plane strain on various BiInO.sub.3 phases. Structural relaxation is carried out to simulate the growth of coherently strained epitaxial films on (001) oriented orthorhombic perovskite substrates. The results are in particular analyzed with respect to commercially available substrates in order to assess the stabilization of new and fundamentally interesting BiInO.sub.3 phases. We find that a pyroxene-like Pcca phase is energetically more favorable than the bulk-like Pna2.sub.1 structure on standard cubic substrate materials, such as SrTiO.sub.3. However, the presence of imaginary phonon modes suggests that this phase is dynamically instable. The bulk-like structure instead is stable over a wide range of lattice in-plane strain, but coherent growth requires substrates with unusually large lattice parameters. We suggest the use of lanthanate substrates in order to produce high-quality thin films of the bulk phase.
doi_str_mv	10.1007/s10853-021-05807-3
format	Article
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subjects	Analysis Density functionals Dielectric films Epitaxy Perovskite Pyroxene Thin films
title	BiInO.sub.3 phases under asymmetric in-plane strain
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