Anomalous Hall Effect for the Phonon Heat Conductivity in Paramagnetic Dielectrics

Kagan, Yu.; Maksimov, L. A.

doi:10.1103/physrevlett.100.145902

Cited by 107 publications

(86 citation statements)

References 10 publications

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“…An accurate evaluation of the integrals in Eq. (13) confirms that the primary contribution to κ xx comes from ω ≈ T = 5K. On the other hand the dominant contribution to κ xy comes from ω ∼ 30K -the phonon Hall effect is due to relatively "hot" phonons.…”

supporting

confidence: 54%

“…We stress that the PHE in TGG relies specifically upon scattering from superstoichiometric Tb 3+ ions, not just scattering from any impurities. This observation was not considered in all previous suggestions 12,13,15 for the mechanism behind the PHE. In this Letter, motivated by the above observation, we show that the PHE originates from the resonant skew scattering of phonons from the crystal field states of superstoichiometric Tb 3+ ions.…”

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confidence: 88%

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Origin of the Phonon Hall Effect in Rare-Earth Garnets

et al. 2014

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The phonon Hall effect has been observed in the paramagnetic insulator, Tb3Gd5O12. A magnetic field applied perpendicularly to a heat current induces a temperature gradient that is perpendicular to both the field and the current. We show that this effect is due to resonant skew scattering of phonons from the crystal field states of superstoichiometric Tb 3+ ions. This scattering originates from the coupling between the quadrupole moment of Tb 3+ ions and the lattice strain. The estimated magnitude of the effect is consistent with experimental observations at T ∼ 5 K, and can be significantly enhanced by increasing temperature.PACS numbers: 72.20.Pa, 72.15.Gd When a linear magnetic field is applied perpendicularly to a heat current in a sample of terbium gallium garnet (TGG), Tb 3 Ga 5 O 12 , a transverse temperature gradient is induced in the third perpendicular direction 1,2 . This is the "phonon Hall effect (PHE)". The effect was observed in this insulator at low temperature (T ∼ 5 K), a situation in which there are no mobile charges such as electrons or holes 3 . The Neel temperature of TGG is 0.24 K 4 , so it is a paramagnet at T ∼ 5 K. Hence magnons do not contribute to the heat current and one does not expect a contribution from the magnon Hall effect 5-8 . Phonons are not charged and hence cannot be affected by the Lorentz force which gives rise to the usual classical Hall effect. Therefore the mechanism for the PHE must be related to the spin-orbit interaction. However, the spin-orbit interaction for phonons is not at all obvious, unlike in the anomalous Hall effect and spin Hall effect for electrons [9][10][11] . Thus, an understanding of the origin of the observed PHE is a fundamental problem.So far, there have been a few theoretical attempts to explain the PHE 12-15 . Refs. 12 and 13 assumed a Ramantype interaction between the spin of stoichiometric Tb 3+ ions and the phonon. This interaction results in "elliptically polarized" phonons. According to 12,13, the "elliptic polarization", in combination with scattering from impurities, leads to the PHE. In this scenario the type of impurity is unimportant and hence phonon -impurity scattering is considered in the leading Born approximation. This is an intrinsic-extrinsic scenario, i.e., the "elliptic polarization" is an intrinsic effect and the scattering from impurities is an extrinsic effect. The major problem with this scenario was realized in Ref. 14 -in spite of the "elliptic polarization" the Born approximation does not result in the PHE. Ref. 14 attempted to go beyond the leading Born approximation in impurity scattering. However, the problem has not been resolved yet. An intrinsic mechanism for the PHE, based on the Berry curvature of phonon bands, was suggested in Ref. 15. This is similar to the Berry curvature mechanism in the Hall effect for light 16 . The Berry curvature mechanism is certainly valid for materials with specially structured phonon bands, however, it is hard to see how the mechanism can be realized in TGG which has the simple...

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confidence: 54%

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confidence: 88%

Origin of the Phonon Hall Effect in Rare-Earth Garnets

et al. 2014

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“…Recently there has been surging experimental interest in studying the thermal Hall effect in various systems, such as the phonon Hall effect [2,3], magnon Hall effect [4], and so on. There are also many theoretical efforts to study these phenomena [5][6][7][8]. However, most of these theoretical studies face a fundamental issue: direct application of the Kubo formula, when done correctly without questionable ''tricks'' [9], always yields unphysical divergence at zero temperature [10,11].…”

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confidence: 99%

Energy Magnetization and the Thermal Hall Effect

2011

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We obtain a set of general formulas for determining magnetizations, including the usual electromagnetic magnetization as well as the gravitomagnetic energy magnetization. The magnetization corrections to the thermal transport coefficients are explicitly demonstrated. Our theory provides a systematic approach for properly evaluating the thermal transport coefficients of magnetic systems, eliminating the unphysical divergence from the direct application of the Kubo formula. For a noninteracting anomalous Hall system, the corrected thermal Hall conductivity obeys the Wiedemann-Franz law.

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“…Strohm et al observed the thermal Hall effect of phonons in a paramagnetic insulator of terbium gallium garnet [72]. The result was explained by the interaction of local magnetic ions with the local orbital angular momentum of oscillating surrounding ions [73,74]. The thermal Hall effect of magnons was also observed in an insulating ferromagnet LU 2 V 2 O 7 with pyrochlore structure [75], and the result was explained in terms of a Dzyaloshinskii-Moriya interaction.…”

Section: Thermal Hall Effect Of Phonons and Magnonsmentioning

confidence: 81%

Thermal Effects in Spintronics: Physics and Applications

Adachi¹,

Maekawa²

2015

Handbook of Spintronics

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Recent progress in investigation of the interplay of spin and heat is reviewed. A special emphasis is placed on the newly discovered example of the thermospin phenomenon termed "spin Seebeck effect" which enables the thermal injection of spin currents from a ferromagnet into attached nonmagnetic metals over a macroscopic scale of several millimeters. The theoretical basis for understanding the spin Seebeck effect is presented, and other thermal spin effects are briefly discussed as well.

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Anomalous Hall Effect for the Phonon Heat Conductivity in Paramagnetic Dielectrics

Cited by 107 publications

References 10 publications

Origin of the Phonon Hall Effect in Rare-Earth Garnets

Origin of the Phonon Hall Effect in Rare-Earth Garnets

Energy Magnetization and the Thermal Hall Effect

Thermal Effects in Spintronics: Physics and Applications

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