Octupolar order in d -orbital Mott insulators

Motivated by experimental and theoretical interest in realizing multipolar orders in d-orbital materials, we discuss the quantum magnetism of J=2 ions which can be realized in spin-orbit coupled oxides with 5d2 transition metal ions. Based on the crystal-field environment, we argue for a splitting o...

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Veröffentlicht in:	Physical review. B 2020-02, Vol.101 (5), p.1, Article 054439
Hauptverfasser:	Paramekanti, A., Maharaj, D. D., Gaulin, B. D.
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Sprache:	eng
Schlagworte:	Antiferromagnetism Dispersion Excitons Face centered cubic lattice Inelastic scattering Insulators Magnetism Perovskites Raman spectra Spin dynamics Transition metals
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creator	Paramekanti, A. Maharaj, D. D. Gaulin, B. D.
description	Motivated by experimental and theoretical interest in realizing multipolar orders in d-orbital materials, we discuss the quantum magnetism of J=2 ions which can be realized in spin-orbit coupled oxides with 5d2 transition metal ions. Based on the crystal-field environment, we argue for a splitting of the J=2 multiplet, leading to a low-lying non-Kramers doublet which hosts quadrupolar and octupolar moments. We discuss a microscopic mechanism whereby the combined perturbative effects of orbital repulsion and antiferromagnetic Heisenberg spin interactions leads to ferro-octupolar coupling between neighboring sites, and stabilizes ferro-octupolar order for a face-centered cubic lattice. This same mechanism is also shown to disfavor quadrupolar ordering. We show that studying crystal field levels via Raman scattering in a magnetic field provides a probe of octupolar order. We study spin dynamics in the ferro-octupolar state using a slave-boson approach, uncovering a gapped and dispersive magnetic exciton. For sufficiently strong magnetic exchange, the dispersive exciton can condense, leading to conventional type-I antiferromagnetic (AFM) order which can preempt octupolar order. Our proposal for ferrooctupolar order, with specific results in the context of a model Hamiltonian, provides a comprehensive understanding of thermodynamics, μSR, x-ray diffraction, and inelastic neutron-scattering measurements on a range of cubic 5d2 double perovskite materials including Ba2ZnOsO6, Ba2CaOsO6, and Ba2MgOsO6. Our proposal for exciton condensation leading to type-I AFM order may be relevant to materials such as Sr2MgOsO6.
doi_str_mv	10.1103/PhysRevB.101.054439
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We show that studying crystal field levels via Raman scattering in a magnetic field provides a probe of octupolar order. We study spin dynamics in the ferro-octupolar state using a slave-boson approach, uncovering a gapped and dispersive magnetic exciton. For sufficiently strong magnetic exchange, the dispersive exciton can condense, leading to conventional type-I antiferromagnetic (AFM) order which can preempt octupolar order. Our proposal for ferrooctupolar order, with specific results in the context of a model Hamiltonian, provides a comprehensive understanding of thermodynamics, μSR, x-ray diffraction, and inelastic neutron-scattering measurements on a range of cubic 5d2 double perovskite materials including Ba2ZnOsO6, Ba2CaOsO6, and Ba2MgOsO6. 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B</title><description>Motivated by experimental and theoretical interest in realizing multipolar orders in d-orbital materials, we discuss the quantum magnetism of J=2 ions which can be realized in spin-orbit coupled oxides with 5d2 transition metal ions. Based on the crystal-field environment, we argue for a splitting of the J=2 multiplet, leading to a low-lying non-Kramers doublet which hosts quadrupolar and octupolar moments. We discuss a microscopic mechanism whereby the combined perturbative effects of orbital repulsion and antiferromagnetic Heisenberg spin interactions leads to ferro-octupolar coupling between neighboring sites, and stabilizes ferro-octupolar order for a face-centered cubic lattice. This same mechanism is also shown to disfavor quadrupolar ordering. We show that studying crystal field levels via Raman scattering in a magnetic field provides a probe of octupolar order. 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B</jtitle><date>2020-02-01</date><risdate>2020</risdate><volume>101</volume><issue>5</issue><spage>1</spage><pages>1-</pages><artnum>054439</artnum><issn>2469-9950</issn><eissn>2469-9969</eissn><abstract>Motivated by experimental and theoretical interest in realizing multipolar orders in d-orbital materials, we discuss the quantum magnetism of J=2 ions which can be realized in spin-orbit coupled oxides with 5d2 transition metal ions. Based on the crystal-field environment, we argue for a splitting of the J=2 multiplet, leading to a low-lying non-Kramers doublet which hosts quadrupolar and octupolar moments. We discuss a microscopic mechanism whereby the combined perturbative effects of orbital repulsion and antiferromagnetic Heisenberg spin interactions leads to ferro-octupolar coupling between neighboring sites, and stabilizes ferro-octupolar order for a face-centered cubic lattice. This same mechanism is also shown to disfavor quadrupolar ordering. We show that studying crystal field levels via Raman scattering in a magnetic field provides a probe of octupolar order. We study spin dynamics in the ferro-octupolar state using a slave-boson approach, uncovering a gapped and dispersive magnetic exciton. For sufficiently strong magnetic exchange, the dispersive exciton can condense, leading to conventional type-I antiferromagnetic (AFM) order which can preempt octupolar order. Our proposal for ferrooctupolar order, with specific results in the context of a model Hamiltonian, provides a comprehensive understanding of thermodynamics, μSR, x-ray diffraction, and inelastic neutron-scattering measurements on a range of cubic 5d2 double perovskite materials including Ba2ZnOsO6, Ba2CaOsO6, and Ba2MgOsO6. 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subjects	Antiferromagnetism Dispersion Excitons Face centered cubic lattice Inelastic scattering Insulators Magnetism Perovskites Raman spectra Spin dynamics Transition metals
title	Octupolar order in d -orbital Mott insulators
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