Charge ordering in Ir dimers in the ground state of Ba5AlIr2O11

It has been well established experimentally that the interplay of electronic correlations and spin-orbit interactions in Ir4+ and Ir5+ oxides results in insulating Jeff = 1/2 and Jeff = 0 ground states, respectively. However, in compounds where the structural dimerization of iridium ions is favorabl...

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Veröffentlicht in:	Physical review. B 2022-02, Vol.105 (7)
Hauptverfasser:	Katukuri, Vamshi M., Lu, Xingye, McNally, D. E., Dantz, Marcus, Strocov, Vladimir N., Sala, M. Moretti, Upton, M. H., Terzic, J., Cao, G., Yazyev, Oleg V., Schmitt, Thorsten
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Schlagworte:	CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY electronic structure iridates quantum chemistry methods resonant inelastic x-ray scattering spin-orbit coupling
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container_title	Physical review. B
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creator	Katukuri, Vamshi M. Lu, Xingye McNally, D. E. Dantz, Marcus Strocov, Vladimir N. Sala, M. Moretti Upton, M. H. Terzic, J. Cao, G. Yazyev, Oleg V. Schmitt, Thorsten
description	It has been well established experimentally that the interplay of electronic correlations and spin-orbit interactions in Ir4+ and Ir5+ oxides results in insulating Jeff = 1/2 and Jeff = 0 ground states, respectively. However, in compounds where the structural dimerization of iridium ions is favorable, the direct Ir d-d hybridization can be significant and takes a key role. Here, in this study, we investigate the effects of direct Ir d-d hybridization in comparison with electronic correlations and spin-orbit coupling in Ba5AlIr2O11, a compound with Ir dimers. Using a combination of ab initio many-body wave-function quantum chemistry calculations and resonant inelastic x-ray scattering experiments, we elucidate the electronic structure of Ba5AlIr2O11. We find excellent agreement between the calculated and the measured spin-orbit excitations. Contrary to expectations, the analysis of the many-body wave function shows that the two Ir (Ir4+ and Ir5+) ions in the Ir2O9 dimer unit in this compound preserve their local Jeff character close to 1/2 and 0, respectively. The local point group symmetry at each of the Ir ions plays an important role, significantly limiting the direct d-d hybridization. Our results emphasize that minute details in the local crystal field environment can lead to dramatic differences in the electronic states in iridates and 5d oxides in general.
doi_str_mv	10.1103/PhysRevB.105.075114
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E. ; Dantz, Marcus ; Strocov, Vladimir N. ; Sala, M. Moretti ; Upton, M. H. ; Terzic, J. ; Cao, G. ; Yazyev, Oleg V. ; Schmitt, Thorsten</creator><creatorcontrib>Katukuri, Vamshi M. ; Lu, Xingye ; McNally, D. E. ; Dantz, Marcus ; Strocov, Vladimir N. ; Sala, M. Moretti ; Upton, M. H. ; Terzic, J. ; Cao, G. ; Yazyev, Oleg V. ; Schmitt, Thorsten ; Argonne National Laboratory (ANL), Argonne, IL (United States)</creatorcontrib><description>It has been well established experimentally that the interplay of electronic correlations and spin-orbit interactions in Ir4+ and Ir5+ oxides results in insulating Jeff = 1/2 and Jeff = 0 ground states, respectively. However, in compounds where the structural dimerization of iridium ions is favorable, the direct Ir d-d hybridization can be significant and takes a key role. Here, in this study, we investigate the effects of direct Ir d-d hybridization in comparison with electronic correlations and spin-orbit coupling in Ba5AlIr2O11, a compound with Ir dimers. Using a combination of ab initio many-body wave-function quantum chemistry calculations and resonant inelastic x-ray scattering experiments, we elucidate the electronic structure of Ba5AlIr2O11. We find excellent agreement between the calculated and the measured spin-orbit excitations. Contrary to expectations, the analysis of the many-body wave function shows that the two Ir (Ir4+ and Ir5+) ions in the Ir2O9 dimer unit in this compound preserve their local Jeff character close to 1/2 and 0, respectively. The local point group symmetry at each of the Ir ions plays an important role, significantly limiting the direct d-d hybridization. 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Using a combination of ab initio many-body wave-function quantum chemistry calculations and resonant inelastic x-ray scattering experiments, we elucidate the electronic structure of Ba5AlIr2O11. We find excellent agreement between the calculated and the measured spin-orbit excitations. Contrary to expectations, the analysis of the many-body wave function shows that the two Ir (Ir4+ and Ir5+) ions in the Ir2O9 dimer unit in this compound preserve their local Jeff character close to 1/2 and 0, respectively. The local point group symmetry at each of the Ir ions plays an important role, significantly limiting the direct d-d hybridization. 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H.</au><au>Terzic, J.</au><au>Cao, G.</au><au>Yazyev, Oleg V.</au><au>Schmitt, Thorsten</au><aucorp>Argonne National Laboratory (ANL), Argonne, IL (United States)</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Charge ordering in Ir dimers in the ground state of Ba5AlIr2O11</atitle><jtitle>Physical review. B</jtitle><date>2022-02-07</date><risdate>2022</risdate><volume>105</volume><issue>7</issue><issn>2469-9950</issn><eissn>2469-9969</eissn><abstract>It has been well established experimentally that the interplay of electronic correlations and spin-orbit interactions in Ir4+ and Ir5+ oxides results in insulating Jeff = 1/2 and Jeff = 0 ground states, respectively. However, in compounds where the structural dimerization of iridium ions is favorable, the direct Ir d-d hybridization can be significant and takes a key role. Here, in this study, we investigate the effects of direct Ir d-d hybridization in comparison with electronic correlations and spin-orbit coupling in Ba5AlIr2O11, a compound with Ir dimers. Using a combination of ab initio many-body wave-function quantum chemistry calculations and resonant inelastic x-ray scattering experiments, we elucidate the electronic structure of Ba5AlIr2O11. We find excellent agreement between the calculated and the measured spin-orbit excitations. Contrary to expectations, the analysis of the many-body wave function shows that the two Ir (Ir4+ and Ir5+) ions in the Ir2O9 dimer unit in this compound preserve their local Jeff character close to 1/2 and 0, respectively. The local point group symmetry at each of the Ir ions plays an important role, significantly limiting the direct d-d hybridization. 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title	Charge ordering in Ir dimers in the ground state of Ba5AlIr2O11
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