Large magneto-optical Kerr effect and imaging of magnetic octupole domains in an antiferromagnetic metal

Higo, Tomoya; Man, Huiyuan; Gopman, Daniel B.; Wu, Liang; Koretsune, Takashi; Erve, O.M.J. van ‘t; Kabanov, Yuri; Rees, Dylan; Li, Yufan; Suzuki, Michi To; Patankar, Shreyas; Ikhlas, Muhammad; Chien, C. L.; Arita, Ryotaro; Shull, Robert D.; Orenstein, Joseph; Nakatsuji, Satoru

doi:10.1038/s41566-017-0086-z

Cited by 311 publications

(248 citation statements)

References 61 publications

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“…Among many different antiferromagnetic [7][8][9] or artificial antiferromagnetic materials [10,11], the noncollinear chiral antiferromagnets have attracted much interest, due to their remarkable structural, magnetic, and electrotransport properties. The trianglular spin structure of these compounds gives rise to a large anomalous Hall effect (AHE) [12,13], thermoelectric effect [14][15][16], magneto-optical Kerr effect [17,18], and spin Hall effect (SHE) [19]. Inspired by experimental work in Mn 3 Ir [19], ab initio calculations confirmed large anisotropic anomalous Hall current and spin Hall current in these materials [20], while predicting that charge current is also spin polarized [21].…”

Section: Introductionmentioning

confidence: 99%

Noncollinear antiferromagnetic Mn3Sn films

Μάρκου

Taylor

Kalache

et al. 2018

Phys. Rev. Materials

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Noncollinear hexagonal antiferromagnets with almost zero net magnetization were recently shown to demonstrate giant anomalous Hall effect. Here, we present the structural and magnetic properties of noncollinear antiferromagnetic Mn 3 Sn thin films heteroepitaxially grown on Y:ZrO 2 (111) substrates with a Ru underlayer. The Mn 3 Sn films were crystallized in the hexagonal D0 19 structure with c-axis preferred (0001) crystal orientation. The Mn 3 Sn films are discontinuous, forming large islands of approximately 400 nm in width, but are chemical homogeneous and characterized by near perfect heteroepitaxy. Furthermore, the thin films show weak ferromagnetism with an in-plane uncompensated magnetization of M = 34 kA/m and coercivity of μ 0 H c = 4.0 mT at room temperature. Additionally, the exchange bias effect was studied in Mn 3 Sn/Py bilayers. Exchange bias fields up to μ 0 H EB = 12.6 mT can be achieved at 5 K. These results show Mn 3 Sn films to be an attractive material for applications in antiferromagnetic spintronics.

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Section: Introductionmentioning

confidence: 99%

Noncollinear antiferromagnetic Mn3Sn films

Μάρκου

Taylor

Kalache

et al. 2018

Phys. Rev. Materials

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“…In most ferri/ferromagnetic films, |θ K | increases proportionally with magnetization, i.e., |θ K | = K s M , with K s being a coefficient within 0.2–2° T −1 (the shaded region in Figure ). Mn 3 Sn, as an antiferromagnetic metal, has a large MOKE with K s = 25.6° T −1 while for antiferromagnetic insulators, K s has a value in the range of 10–20° T −1 …”

Section: Magnetooptical Materialsmentioning

confidence: 99%

“…Mn 3 Sn, an antiferromagnetic metal, has a large MOKE with K s = 25.6° T −1 while for antiferromagnetic insulators, K s has a value in the range of 10–20° T −1 . Reproduced with permission . Copyright 2018, Springer Nature.…”

Section: Magnetooptical Materialsmentioning

confidence: 99%

Advanced Materials and Device Architectures for Magnetooptical Spatial Light Modulators

Kharratian

Ürey

Onbaşlı

2019

Advanced Optical Materials

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Faraday and Kerr rotations are magnetooptical (MO) effects used for rotating the polarization of light in transmission and reflection from a magnetized medium, respectively. MO effects combined with intrinsically fast magnetization reversal, which can go down to a few tens of femtoseconds or less, can be applied in magnetooptical spatial light modulators (MOSLMs) promising for nonvolatile, ultrafast, and high‐resolution spatial modulation of light. With the recent progress in low‐power switching of magnetic and MO materials, MOSLMs may lead to major breakthroughs and benefit beyond state‐of‐the‐art holography, data storage, optical communications, heads‐up displays, virtual and augmented reality devices, and solid‐state light detection and ranging (LIDAR). In this study, the recent developments in the growth, processing, and engineering of advanced materials with high MO figures of merit for practical MOSLM devices are reviewed. The challenges with MOSLM functionalities including the intrinsic weakness of MO effect and large power requirement for switching are assessed. The suggested solutions are evaluated, different driving systems are investigated, and resulting device architectures are benchmarked. Finally, the research opportunities on MOSLMs for achieving integrated, high‐contrast, and low‐power devices are presented.

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“…Accordingly, the orientation of the AFM spin axis in FeRh can be controlled by the direction of the cooling field applied above the MPT temperature of FeRh. [96,[98][99][100][101][102][103][104][105] At the same time, another major breakthrough in AFM spintronics came from the discovery of the Berry-curvatureinduced anomalous Hall effect (AHE). Similar to the AMR effect in FM materials, the resistance is higher when the AFM spin axis is parallel to the measuring current and is lower when the AFM spin axis is transverse to the current.…”

Section: Introduction To the Topological Afm Spintronicsmentioning

confidence: 99%

Electric‐Field Control of Magnetic Order: From FeRh to Topological Antiferromagnetic Spintronics

Feng

Yan

Liu

2018

Adv Elect Materials

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approach that is capable of suppressing Joule heating is highly desirable from an energy perspective.Under this background, electric-field control of magnetism emerges in the field of multiferroics, which is expected to reduce the energy consumption of information storage by several orders of magnitude, to fJ bit −1 or even aJ bit −1 . [4][5][6][7][8][9][10][11] In single-phase multiferroic materials, which consists of more than one ferroic order, if there is coupling among different ferroic orders, for example, the magnetoelectric coupling between the ferroelectric (FE) and FM orders, the magnetism can be conveniently controlled by electrical switching of the ferroelectricity, such as in YMnO 3 , BiFeO 3 , and TbMnO 3 . However, the magnetic order in these materials is typically antiferromagnetic, which is difficult to detect, and the magnetoelectric coupling is rather weak; [12][13][14] moreover, intrinsic single-phase multiferroic materials are rare because of contradicting symmetry and physical requirements. [15] All these factors prevent single-phase multiferroic materials from practical device applications.Alternatively, the electric-field control of magnetism can be achieved in heterostructures via other means: (1) in FM/FE composite heterostructures, the magnetism of the FM thin films can be modulated by the piezoelectric strain triggered by electric fields applied onto the ferroelectric substrates; [8] (2) in FM/dielectric composite heterostructures with ultrathin FM thin films, the magnetism can be tailored by the electrostatic doping; [8] (3) in FM/multiferroic composite heterostructures, the magnetism of the FM thin film layers can be varied by electric fields through the interfacial magnetic exchange coupling, such as in Co 0.9 Fe 0.1 /BiFeO 3 heterostructures. [16] Typically, the modulation of magnetism by electric fields in multiferroic heterostructures results in variations in the magnetization, coercivity fields, or magnetic anisotropy of the ferromagnetic materials. In addition, the key scientific issue of controlling magnetic properties using an electric field has been carefully elaborated in previous Reviews. [17,18] Among them, the change of magnetization (ΔM) upon external electric fields (ΔE) yields the simplified magnetoelectric coupling coefficient (strictly speaking, the magnetoelectric coupling coefficient should be described as a tensor; please refer to the previous Reviews) [17,18] α = μ 0 ΔM/ΔE, where μ 0 is the permittivity of free space. Compared with single-phase multiferroics, α in multiferroic heterostructures can be significantly greater, for example, it reaches 1.08 × 10 −7 s m −1 Using an electric field instead of an electric current (or a magnetic field) to tailor the electronic properties of magnetic materials is promising for realizing ultralow-energy-consuming memory devices because of the suppression of Joule heating, especially when the devices are scaled down to the nanoscale. Here, recent results on giant magnetization and resistivity modulation in a metamagnetic inte...

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Large magneto-optical Kerr effect and imaging of magnetic octupole domains in an antiferromagnetic metal

Cited by 311 publications

References 61 publications

Noncollinear antiferromagnetic Mn3Sn films

Noncollinear antiferromagnetic Mn3Sn films

Advanced Materials and Device Architectures for Magnetooptical Spatial Light Modulators

Electric‐Field Control of Magnetic Order: From FeRh to Topological Antiferromagnetic Spintronics

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