Correlation-induced octahedral rotations in SrMoO3

Alexander Hampel; Jeremy Lee-Hand; Antoine Georges; Cyrus E. Dreyer

doi:10.1103/PhysRevB.104.035102

Correlation-induced octahedral rotations in SrMoO3

Alexander Hampel
, Jeremy Lee-Hand
, Antoine Georges
, Cyrus E. Dreyer

Simons Foundation
Stony Brook University
Collège de France
IP Paris
University of Geneva

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

14 Scopus citations

Abstract

Distortions of the oxygen octahedra influence the fundamental electronic structure of perovskite oxides, such as their bandwidth and exchange interactions. Utilizing a fully ab initio methodology based on density functional theory plus dynamical mean field theory (DFT+DMFT), we study the crystal and magnetic structure of SrMoO3. Comparing our results with DFT+U performed on the same footing, we find that DFT+U overestimates the propensity for magnetic ordering, as well as the octahedral rotations, leading to a different ground-state structure. This demonstrates that structural distortions can be highly sensitive to electronic correlation effects and to the considered magnetic state, even in a moderately correlated metal such as SrMoO3. Moreover, by comparing different downfolding schemes, we demonstrate the robustness of the DFT+DMFT method for obtaining structural properties, highlighting its versatility for applications to a broad range of materials.

Original language	English
Article number	035102
Journal	Physical Review B
Volume	104
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevB.104.035102
State	Published - Jul 15 2021

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10.1103/PhysRevB.104.035102

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title = "Correlation-induced octahedral rotations in SrMoO3",

abstract = "Distortions of the oxygen octahedra influence the fundamental electronic structure of perovskite oxides, such as their bandwidth and exchange interactions. Utilizing a fully ab initio methodology based on density functional theory plus dynamical mean field theory (DFT+DMFT), we study the crystal and magnetic structure of SrMoO3. Comparing our results with DFT+U performed on the same footing, we find that DFT+U overestimates the propensity for magnetic ordering, as well as the octahedral rotations, leading to a different ground-state structure. This demonstrates that structural distortions can be highly sensitive to electronic correlation effects and to the considered magnetic state, even in a moderately correlated metal such as SrMoO3. Moreover, by comparing different downfolding schemes, we demonstrate the robustness of the DFT+DMFT method for obtaining structural properties, highlighting its versatility for applications to a broad range of materials.",

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AU - Hampel, Alexander

AU - Lee-Hand, Jeremy

AU - Georges, Antoine

AU - Dreyer, Cyrus E.

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Y1 - 2021/7/15

N2 - Distortions of the oxygen octahedra influence the fundamental electronic structure of perovskite oxides, such as their bandwidth and exchange interactions. Utilizing a fully ab initio methodology based on density functional theory plus dynamical mean field theory (DFT+DMFT), we study the crystal and magnetic structure of SrMoO3. Comparing our results with DFT+U performed on the same footing, we find that DFT+U overestimates the propensity for magnetic ordering, as well as the octahedral rotations, leading to a different ground-state structure. This demonstrates that structural distortions can be highly sensitive to electronic correlation effects and to the considered magnetic state, even in a moderately correlated metal such as SrMoO3. Moreover, by comparing different downfolding schemes, we demonstrate the robustness of the DFT+DMFT method for obtaining structural properties, highlighting its versatility for applications to a broad range of materials.

AB - Distortions of the oxygen octahedra influence the fundamental electronic structure of perovskite oxides, such as their bandwidth and exchange interactions. Utilizing a fully ab initio methodology based on density functional theory plus dynamical mean field theory (DFT+DMFT), we study the crystal and magnetic structure of SrMoO3. Comparing our results with DFT+U performed on the same footing, we find that DFT+U overestimates the propensity for magnetic ordering, as well as the octahedral rotations, leading to a different ground-state structure. This demonstrates that structural distortions can be highly sensitive to electronic correlation effects and to the considered magnetic state, even in a moderately correlated metal such as SrMoO3. Moreover, by comparing different downfolding schemes, we demonstrate the robustness of the DFT+DMFT method for obtaining structural properties, highlighting its versatility for applications to a broad range of materials.

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Correlation-induced octahedral rotations in SrMoO3

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