Record thermopower found in an IrMn-based spintronic stack

Tu, Shiao‐Chun; Ziman, Timothy; Yu, Guoqiang; Wan, Caihua; Hu, Junfeng; Wu, Hao; Wang, Hanchen; Liu, Mengchao; Liu, Chuan‐Pu; Guo, Chenyang; Zhang, Jianyu; Z., Marco A. Cabero; Zhang, Youguang; Gao, Peng; Liu, Song; Yu, Dapeng; Han, X. F.; Hallsteinsen, Ingrid; Gilbert, Dustin A.; Matsuo, Mamoru; Ohnuma, Yuichi; Wölfle, P.; Wang, Kang L.; Ansermet, Jean-Philippe; Maekawa, Sadamichi; Yu, Haiming

doi:10.1038/s41467-020-15797-6

Cited by 19 publications

(31 citation statements)

References 75 publications

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“…6 is associated with the Joule heating of the device by the applied current, and its effect on the AFM state, namely the spin fluctuations of the Mn atoms which are bigger when the device temperature is closer to the Néel temperature. It is worth noting that similar behavior has also been measured in the tunnel anisotropic magnetoresistance of Ir0.2Mn0.8/MgO/Ta magnetic tunnel junctions [55], as well as in the Seebeck coefficient of thin IrMn3 films [56]. In the latter work, the Néel temperature of IrMn3 is measured to be ~ 350 K for a 4 nm thin film, while the Néel temperature for bulk IrMn3 is around 700 K.…”

Section: Discussionsupporting

confidence: 77%

“…In particular, it is worth noting that Néel temperature reduction as a function of the thickness of IrMn3 has been previously observed. Bulk IrMn3 has a Néel temperature above 700 K [57], which can be reduced to room temperature for thickness values below 3 nm [55,56]. The reduction of the Néel temperature (while still keeping it above room temperature by selecting an appropriate IrMn3 thickness) will be accompanied by a reduction of the exchange constant, which in turn affects the threshold current.…”

Section: Discussionmentioning

confidence: 99%

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Observation of current-induced switching in non-collinear antiferromagnetic IrMn3 by differential voltage measurements

et al. 2021

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There is accelerating interest in developing memory devices using antiferromagnetic (AFM) materials, motivated by the possibility for electrically controlling AFM order via spin-orbit torques, and its read-out via magnetoresistive effects. Recent studies have shown, however, that high current densities create non-magnetic contributions to resistive switching signals in AFM/heavy metal (AFM/HM) bilayers, complicating their interpretation. Here we introduce an experimental protocol to unambiguously distinguish current-induced magnetic and nonmagnetic switching signals in AFM/HM structures, and demonstrate it in IrMn3/Pt devices. A six-terminal double-cross device is constructed, with an IrMn3 pillar placed on one cross. The differential voltage is measured between the two crosses with and without IrMn3 after each switching attempt. For a wide range of current densities, reversible switching is observed only when write currents pass through the cross with the IrMn3 pillar, eliminating any possibility of non-magnetic switching artifacts. Micromagnetic simulations support our findings, indicating a complex domain-mediated switching process.

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Section: Discussionsupporting

confidence: 77%

Section: Discussionmentioning

confidence: 99%

Observation of current-induced switching in non-collinear antiferromagnetic IrMn3 by differential voltage measurements

et al. 2021

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“…In addition to the magnetoresistance sensors that have already been widely used, sub-field researches on novel spin-orbitronic devices are desired for versatile specific IoT applications, including flexible SOT devices for wearable equipment ( Lee et al., 2015 ), SOT-driven antiferromagnetic memories for security and magnetic field-immune applications, as well as spin-orbit THz emitters utilizing the ultrafast spin dynamics and the inverse spin Hall effect (ISHE) in FM/HM bilayers for rapid data communications ( Kampfrath et al., 2013 ; Seifert et al., 2016 ; Wu et al., 2017 ). Besides, spin-orbitronic devices based on MTJs could also harvest the heat dissipation on a chip or from the environment and generate sufficient thermopower by magneto-Seebeck effects ( Liebing et al., 2011 ; Walter et al., 2011 ; Boehnke et al., 2017 ; Tu et al., 2020 ; Friesen et al., 2019 ). In summary, the discovery of SOT-induced electrical manipulation of ferromagnet may be just a beginning and the party of spin-orbit related researches and applications will continue to prosper.…”

Section: Emerging Spin-orbitronic Devices Applicationsmentioning

confidence: 99%

Prospect of Spin-Orbitronic Devices and Their Applications

et al. 2020

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Summary Science, engineering, and medicine ultimately demand fast information processing with ultra-low power consumption. The recently developed spin-orbit torque (SOT)-induced magnetization switching paradigm has been fueling opportunities for spin-orbitronic devices, i.e., enabling SOT memory and logic devices at sub-nano second and sub-picojoule regimes. Importantly, spin-orbitronic devices are intrinsic of nonvolatility, anti-radiation, unlimited endurance, excellent stability, and CMOS compatibility, toward emerging applications, e.g., processing in-memory, neuromorphic computing, probabilistic computing, and 3D magnetic random access memory. Nevertheless, the cutting-edge SOT-based devices and application remain at a premature stage owing to the lack of scalable methodology on the field-free SOT switching. Moreover, spin-orbitronics poises as an interdisciplinary field to be driven by goals of both fundamental discoveries and application innovations, to open fascinating new paths for basic research and new line of technologies. In this perspective, the specific challenges and opportunities are summarized to exert momentum on both research and eventual applications of spin-orbitronic devices.

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“…The recently observed ftacular temperature dependence of the thermopower in a magnetic heterostructure involving the antiferromagnetic metal IrMn [1] suggests that the spin fluctuations near the antiferromagnetic transition may be responsible for the observed peak at the ordering temperature. This finding is all the more interesting in that the magnetic transition temperature may be tuned by the thickness of the IrMn layers to be at room temperature, which makes the effect highly promising for applications.…”

Section: Introductionmentioning

confidence: 98%

“…A detailed model calculation of the electrical resistivity of antiferromagnetic metals, in the framework of the Self-Consistent Renormalization Theory of spin fluctuations in itinerant magnets [5,6] has been worked out by Ueda [7]. In all these previous studies the anomalies near the transition found for the transport properties appeared to be relatively weak and cannot account for the prominent peak found in the thermopower as a function of temperature or as a function of layer thickness of an IrMn heterostructure [1].…”

Section: Introductionmentioning

confidence: 99%

Theory of record thermopower near a finite temperature magnetic phase transition in IrMn

Wölfle

Ziman

2021

Phys. Rev. B

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The effect of scattering of conduction electrons by dynamical spin fluctuations on the thermopower in metals near a thermal phase transition into an antiferromagnetic phase is considered. We are interested in a transition at room temperature, as has been studied in a heterostructure involving layers of IrMn. We show that the electrical resistivity exhibits a narrow but low peak at the transition, which may be ddifficult to detect on top of the main contributions induced by phonons and impurities. By contrast, the thermopower is found to exhibit a prominent peak both as a function of temperature T for fixed layer thickness tAF M and as a function of tAF M for fixed T. We conjecture that the transition temperature Tc is a function of both tAF M and the Fermi energy F . Both dependencies give rise to a sharp peak of the thermopower as a function of T or tAF M near the transition. The estimated magnitude of the peak for the case of three-dimensional longitudinal spin fluctuations is in good agreement with experiment.

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Record thermopower found in an IrMn-based spintronic stack

Cited by 19 publications

References 75 publications

Observation of current-induced switching in non-collinear antiferromagnetic IrMn3 by differential voltage measurements

Observation of current-induced switching in non-collinear antiferromagnetic IrMn3 by differential voltage measurements

Prospect of Spin-Orbitronic Devices and Their Applications

Theory of record thermopower near a finite temperature magnetic phase transition in IrMn

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