Photonic Signatures of Spin-Driven Ferroelectricity in Multiferroic Dielectric Oxides

We study the dispersion and scattering properties of electromagnetic modes coupled to a helically ordered spin lattice hosted by a dielectric oxide with a ferroelectric polarization driven by vector spin chirality. Quasianalytical approaches and full-fledged numerics evidence the formation of a chir...

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Veröffentlicht in:	Physical review letters 2021-09, Vol.127 (12), p.127601-127601, Article 127601
Hauptverfasser:	Jandieri, Vakhtang, Khomeriki, Ramaz, Chotorlishvili, Levan, Watanabe, Koki, Erni, Daniel, Werner, Douglas H., Berakdar, Jamal
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Sprache:	eng
Schlagworte:	Chirality Coupled modes Dichroism Electromagnetic radiation Ferroelectric materials Ferroelectricity Lattice vibration Maxwell's equations Multiferroic materials Photonic band gaps Photonics Physical Sciences Physics Physics, Multidisciplinary Polarization (spin alignment) Scattering Science & Technology Topology
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container_title	Physical review letters
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creator	Jandieri, Vakhtang Khomeriki, Ramaz Chotorlishvili, Levan Watanabe, Koki Erni, Daniel Werner, Douglas H. Berakdar, Jamal
description	We study the dispersion and scattering properties of electromagnetic modes coupled to a helically ordered spin lattice hosted by a dielectric oxide with a ferroelectric polarization driven by vector spin chirality. Quasianalytical approaches and full-fledged numerics evidence the formation of a chiral magnonic photonic band gap and the presence of gate-voltage dependent circular dichroism in the scattering of electromagnetic waves from the lattice. Gating couples to the emergent ferroelectric polarization and hence, to the underlying vector-spin chirality. The theory relies on solving simultaneously Maxwell's equations coupled to the driven localized spins taking into account their spatial topology and spatial anisotropic interactions. The developed approach is applicable to various settings involving noncollinear spins and multiferroic systems with potential applications in noncollinear magnetophotonics.
doi_str_mv	10.1103/PhysRevLett.127.127601
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Quasianalytical approaches and full-fledged numerics evidence the formation of a chiral magnonic photonic band gap and the presence of gate-voltage dependent circular dichroism in the scattering of electromagnetic waves from the lattice. Gating couples to the emergent ferroelectric polarization and hence, to the underlying vector-spin chirality. The theory relies on solving simultaneously Maxwell's equations coupled to the driven localized spins taking into account their spatial topology and spatial anisotropic interactions. 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subjects	Chirality Coupled modes Dichroism Electromagnetic radiation Ferroelectric materials Ferroelectricity Lattice vibration Maxwell's equations Multiferroic materials Photonic band gaps Photonics Physical Sciences Physics Physics, Multidisciplinary Polarization (spin alignment) Scattering Science & Technology Topology
title	Photonic Signatures of Spin-Driven Ferroelectricity in Multiferroic Dielectric Oxides
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