Electric Field Control of Terahertz Polarization in a Multiferroic Manganite with Electromagnons

Shuvaev, A.; Dziom, V.; Pimenov, A.; Schiebl, M.; Mukhin, A. A.; Komarek, A. C.; Finger, T.; Braden, M.

doi:10.1103/physrevlett.111.227201

Cited by 47 publications

(18 citation statements)

References 32 publications

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“…This mode was previously found [54] to lower in energy for isotopically pure 65 CuO in comparison to 63 CuO, demonstrating that it results from an LA motion of Cu 2+ ions along (101), modulating the strongest superexchange interaction J 80 meV [31]. The three principal Raman modes were at the same energies for 65 CuO and 63 CuO, as expected for vibrations associated only with oxygen motion [54], while they shifted to lower frequencies for Cu 18 O than for Cu 16 O [59]. Further evidence for the magnetically induced zone folding of phonons in CuO was reported by Kuz'menko et al, who reported additional IR-active modes that were linked to phonon modes at the X and A points [51].…”

Section: Results: Ir-active Phononssupporting

confidence: 67%

“…Electromagnons-spin waves that become electric-dipole active in a magnetoelectric phase-are a recently discovered quasiparticle excitation that provide a window into the important spin interactions of magnetoelectrics [11][12][13][14][15][16][17]. The electric-field tuning of electromagnons in DyMnO 3 , an improper ferroelectric multiferroic [18], and of magnons in bulk BiFeO 3 , a proper ferroelectric multi-* j.lloyd-hughes@warwick.ac.uk ferroic [19], establish the potential of spin waves in data processing and communications [20].…”

Section: Introductionmentioning

confidence: 99%

“…A DM electromagnon has been reported in TbMnO 3 , substantially weaker than the Heisenberg electromagnons [16]. The electric-field control of polarization of terahertz (THz) radiation has recently been demonstrated using DM electromagnons in DyMnO 3 [18].…”

Section: Introductionmentioning

confidence: 99%

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Influence of nonmagnetic Zn substitution on the lattice and magnetoelectric dynamical properties of the multiferroic material CuO

et al. 2014

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Dynamic magnetoelectric coupling in the improper ferroelectric Cu 1−x Zn x O (x = 0, x = 0.05) was investigated using terahertz time-domain spectroscopy to probe electromagnon and magnon modes. Zinc substitution was found to reduce the antiferromagnetic ordering temperature and widen the multiferroic phase, under the dual influences of spin dilution and a reduction in unit-cell volume. The impact of Zn substitution on lattice dynamics was elucidated by Raman and Fourier-transform spectroscopy, and shell-model calculations. Pronounced softenings of the A u phonons, active along the direction of ferroelectric polarization, occur in the multiferroic state of Cu 1−x Zn x O, and indicate strong spin-phonon coupling. The commensurate antiferromagnetic phase also exhibits spin-phonon coupling, as evidenced by a Raman-active zone-folded acoustic phonon, and spin dilution reduces the spin-phonon coupling coefficient. While the phonon and magnon modes broaden and shift as a result of alloy-induced disorder, the electromagnon is relatively insensitive to Zn substitution, increasing in energy without widening. The results demonstrate that electromagnons and dynamic magnetoelectric coupling can be maintained even in disordered spin systems.

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Section: Results: Ir-active Phononssupporting

confidence: 67%

Section: Introductionmentioning

confidence: 99%

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Influence of nonmagnetic Zn substitution on the lattice and magnetoelectric dynamical properties of the multiferroic material CuO

et al. 2014

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“…For example, directional dichroism might reveal the character of the spin excitation observed in the THz spectra and identify whether it corresponds to a pure magnon or electromagnon, as in Ni 3 TeO 6 . Unfortunately, since the magnetic excitation lies below 8 cm -1 , more precise transmission measurements with a spectrometer based on backward-wave oscillator sources 39 and a crystal with diameter at least 10 mm would be required. In addition, using single crystals, one can avoid possible impurities often present at grain boundaries of polycrystalline samples, thus the anomaly seen at 23 K could be absent or better resolved.…”

Section: Spin and Lattice Excitationsmentioning

confidence: 99%

Structural and spectroscopic properties of the polar antiferromagnet Ni2MnTeO6

et al. 2018

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We present a structural and spectroscopic study of a new compound Ni 2 MnTeO 6 , closely related to the polar antiferromagnet Ni 3 TeO 6 known to show a colossal magnetoelectric effect and pronounced elementary magnetoelectric excitations. For the first time, we prepared single crystals and polycrystalline samples of Ni 2 MnTeO 6 showing the same polar structure as Ni 3 TeO 6 from room temperature down to 4 K with the R3 space group symmetry. Magnetic and dielectric measurements have indicated an antiferromagnetic phase transition at T N ≈70 K, almost 20 K higher than that of Ni 3 TeO 6. Extensive infrared, Raman and THz spectroscopy experiments were employed for investigating lattice and spin excitations, revealing all phonons predicted by the factor group analysis. THz spectra below T N reveal one new excitation, which is strongly influenced by external magnetic field, thus assigned to a magnon.

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“…[184] Pimenov et al observed the new collective excitation corresponding to this multiferroic state known as electromagnon, i.e., electric-dipole active magnetic excitation in the imaginary part of the THz dielectric constant for GdMnO 3 and TbMnO 3 . [184,[187][188][189] This electromagnon has been reported as the rotational mode of the spiral spin plane which showed the absorption mode for E ω perpendicular to the plane of the spiral spin order. Such studies were further carried out with enhanced precision.…”

Section: Thz Studies On Multiferroic Rmnomentioning

confidence: 86%

Terahertz Electrodynamics in Transition Metal Oxides

Prajapati

Dagar

et al. 2019

Advanced Optical Materials

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adom.201900958. 2−y 2 , d z 2 ) levels. [35] The splitting of the d-orbital was successfully explained by the crystal field theory. The ground state properties of these materials are mainly governed by the two interactions; i) the electron correlations (U) and, ii) SOC (λ) in the crystal field split narrow bands. [36] Among d electron systems, electrons in 3d TMOs experiences large electron correlations due to localized nature of 3d orbitals. The idea of electron-electron interaction was given by Sir N. F. Mott in 1949. It originated from the fact that the NiO was expected to be a metal according to the band theory, while the experiments showed insulating behavior. [37][38][39][40][41] This disagreement of experiments with the theory was explained by Hubbard who attributed the insulating state to the splitting

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Electric Field Control of Terahertz Polarization in a Multiferroic Manganite with Electromagnons

Cited by 47 publications

References 32 publications

Influence of nonmagnetic Zn substitution on the lattice and magnetoelectric dynamical properties of the multiferroic material CuO

Influence of nonmagnetic Zn substitution on the lattice and magnetoelectric dynamical properties of the multiferroic material CuO

Structural and spectroscopic properties of the polar antiferromagnet Ni2MnTeO6

Terahertz Electrodynamics in Transition Metal Oxides

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