Magnon-drag thermopower and Nernst coefficient in Fe, Co, and Ni

Watzman, Sarah J.; Duine, R. A.; Tserkovnyak, Yaroslav; Boona, Stephen R.; Jin, Hyungyu; Prakash, Arati; Zheng, Yuanhua; Heremans, Joseph P.

doi:10.1103/physrevb.94.144407

Cited by 124 publications

(125 citation statements)

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“…[29] and [30], respectively, the room-temperature magnonic contribution S to the thermopower of symmetric tunnel junctions is obtained then to be significant when compared with the free-electron one. Similar estimates have been made in the context of the measured bulk thermopower in metallic ferromagnets [8].…”

Section: Discussion and Outlooksupporting

confidence: 74%

“…1. At low temperatures, i.e., T T C ,T F (with T C and T F being the Curie and Fermi temperature, respectively), the electric current is controlled by the voltage V applied to the 2469-9950/2017/96(9)/094429 (8) 094429-1 ©2017 American Physical Society…”

Section: A Phenomenology Of Magnetic Pumpingmentioning

confidence: 99%

“…On another front, new experimental evidence suggests that the magnon drag in the ferromagnetic bulk is playing a fundamental role in the thermopower: Watzman et al [8] observe a thermopower scaling as T 3/2 (and thus dominating over the single-electron diffusive contribution ∝T ) over a broad temperature range in elemental transition metals, in agreement with the theoretically predicted magnon-drag contribution associated with the magnonic heat flux [9,10]. These findings call for a reassessment of the mechanism of the Seebeck effect in MTJs, where the relative importance of the electronic and magnonic contributions may be expected to parallel that in the bulk [11].…”

Section: Introductionmentioning

confidence: 99%

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Theory of the magnon-mediated tunnel magneto-Seebeck effect

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The tunnel magneto-Seebeck effect is the dependence of the thermopower of magnetic tunnel junctions on the magnetic configuration. It is conventionally interpreted in terms of a thermoelectric generalization of the tunnel magnetoresistance. Here, we investigate the heat-driven electron transport in these junctions associated with electron-magnon scattering, using stochastic Landau-Lifshitz phenomenology and quantum kinetic theory. Our findings challenge the widely accepted single-electron picture of the tunneling thermopower in magnetic junctions.

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Section: Discussion and Outlooksupporting

confidence: 74%

Section: A Phenomenology Of Magnetic Pumpingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Theory of the magnon-mediated tunnel magneto-Seebeck effect

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“…According to Eqs. (38) and (40) the function y 1 is also stationary at H = H ⊥ , but it has a minimum only for η < 1, while an inflection point for η = 1, and a maximum otherwise. The resulting dependence on η of Eq.…”

Section: A Spin and Heat Transportmentioning

confidence: 92%

Magnon-polaron transport in magnetic insulators

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We theoretically study the effects of strong magnetoelastic coupling on the transport properties of magnetic insulators. We develop a Boltzmann transport theory for the mixed magnon-phonon modes ("magnon polarons") and determine transport coefficients and the spin diffusion length. Magnon-polaron formation causes anomalous features in the magnetic field and temperature dependence of the spin Seebeck effect when the disorder scattering in the magnetic and elastic subsystems is sufficiently different. Experimental data by Kikkawa et al. [Phys. Rev. Lett. 117, 207203 (2016)] on yttrium iron garnet films can be explained by an acoustic quality that is much better than the magnetic quality of the material. We predict similar anomalous features in the spin and heat conductivity and nonlocal spin transport experiments.

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“…1 To that end, phonon drag had been shown to enhance the Nernst coefficient at low temperatures in certain material systems. 3,4 More recently, Watzman et al reported that the anomalous Nernst coefficient also benefits from magnon drag as shown in single crystal Fe where N ANE is dominated by magnon drag up to 200 K. 5 In this study, we propose using a magnetostrictive metallic metal, Galfenol (Fe 100-x Ga x ), as a pathway to increase the power factor due to its enhanced Nernst coefficient from phonon and magnon coupling, as well as its large intrinsic electrical conductivity. We demonstrate Nernst voltage generation in a coiled Galfenol wire, characterize its Nernst coefficient, and offer an experimental proof-of-concept for a novel and scalable thermoelectric generator ideal for cylindrical heaters.…”

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confidence: 93%

Scalable Nernst thermoelectric power using a coiled galfenol wire

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The Nernst thermopower usually is considered far too weak in most metals for waste heat recovery. However, its transverse orientation gives it an advantage over the Seebeck effect on non-flat surfaces. Here, we experimentally demonstrate the scalable generation of a Nernst voltage in an air-cooled metal wire coiled around a hot cylinder. In this geometry, a radial temperature gradient generates an azimuthal electric field in the coil. A Galfenol (Fe0.85Ga0.15) wire is wrapped around a cartridge heater, and the voltage drop across the wire is measured as a function of axial magnetic field. As expected, the Nernst voltage scales linearly with the length of the wire. Based on heat conduction and fluid dynamic equations, finite-element method is used to calculate the temperature gradient across the Galfenol wire and determine the Nernst coefficient. A giant Nernst coefficient of -2.6 μV/KT at room temperature is estimated, in agreement with measurements on bulk Galfenol. We expect that the giant Nernst effect in Galfenol arises from its magnetostriction, presumably through enhanced magnon-phonon coupling. Our results demonstrate the feasibility of a transverse thermoelectric generator capable of scalable output power from non-flat heat sources.

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Magnon-drag thermopower and Nernst coefficient in Fe, Co, and Ni

Cited by 124 publications

References 50 publications

Theory of the magnon-mediated tunnel magneto-Seebeck effect

Theory of the magnon-mediated tunnel magneto-Seebeck effect

Magnon-polaron transport in magnetic insulators

Scalable Nernst thermoelectric power using a coiled galfenol wire

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