Antiferromagnetic switching driven by the collective dynamics of a coexisting spin glass

Maniv, Eran; Nair, Nityan; Haley, Shannon; Doyle, Spencer; John, Caolan; Cabrini, Stefano; Maniv, Ariel; Ramakrishna, Sanath K.; Tang, Yun; Ercius, Peter; Ramesh, R.; Tserkovnyak, Yaroslav; Reyes, A. P.; Analytis, James

doi:10.1126/sciadv.abd8452

Cited by 38 publications

(64 citation statements)

References 33 publications

(38 reference statements)

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“…agrees with the experimental data in Ref. [38] for Fe intercalations likely corresponding to a-stripe and a-zigzag order.…”

supporting

confidence: 92%

“…Further studies are required to understand the origins of the current-domain coupling which leads to domains parallel to the current pulse being disfavored and whether this is consistent with the spin-glass-mediated spin-orbit torque mechanism proposed in Ref. [38].…”

Section: Discussionmentioning

confidence: 67%

“…( 3), additional deviations from experimental results may come from our use of the pristine x = 1 3 Fe concentration in all PBE+U calculations, as the recent transport and switching experiments [15,38] were performed on Fe x NbS 2 samples with a range of Fe concentrations x ∼ 0.31-0.35. Although NMR data suggest that a spin-glass coexists with the AFM order above and below x = 1 3 and may well be the underlying mechanism for the efficient switching of the ordered magnetic domains [38], we expect that the electronic structure and transport anisotropy of the stripe and zigzag phases, which we focus on in this paper, will not differ significantly between slightly off-stoichiometry structures and the x = 1 3 structure we use in our DFT calculations. Moreover, the NMR measurements, as well as contemporary neutron experiments [33], find evidence of a slight in-plane magnetic moment, in contrast to the earlier neutron studies [14,31].…”

Section: Resistivity Tensor and Switchingmentioning

confidence: 99%

“…4(a) we show the a-b plane of the Fe 1/3 NbS 2 crystal overlaid with the directions of applied currents and measured resistances for the experiments in Refs. [15,38]. In these experiments, DC pulses, J write 1 and J write 2 , were applied in succession along the −k y /[1 20] and k x /[100] crystallographic directions.…”

Section: Resistivity Tensor and Switchingmentioning

confidence: 99%

“…along J probe , are shown in Ref. [38] to be ∼2.5% and ∼1.3% (when normalized to the same DC pulse current density) for Fe intercalations corresponding to x = 0.31 and x = 0.35, respectively; the smaller intercalation was used in Ref. [15] as well.…”

mentioning

confidence: 99%

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Origins of anisotropic transport in the electrically switchable antiferromagnet Fe1/3NbS2

Weber

Neaton

2021

Phys. Rev. B

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Recent experiments on the antiferromagnetic intercalated transition metal dichalcogenide Fe 1/3 NbS 2 have demonstrated reversible resistivity switching by application of orthogonal current pulses below its magnetic ordering temperature, making Fe 1/3 NbS 2 promising for spintronics applications. Here, we perform density functional theory calculations with Hubbard U corrections of the magnetic order, electronic structure, and transport properties of crystalline Fe 1/3 NbS 2 , clarifying the origin of the different resistance states. The two experimentally proposed antiferromagnetic ground states, corresponding to in-plane stripe and zigzag ordering, are computed to be nearly degenerate. In-plane cross sections of the calculated Fermi surfaces are anisotropic for both magnetic orderings, with the degree of anisotropy sensitive to the Hubbard U value. The in-plane resistance, computed within the Kubo linear response formalism using a constant relaxation time approximation, is also anisotropic, supporting a hypothesis that the current-induced resistance changes are due to a repopulating of antiferromagnetic domains. Our calculations indicate that the transport anisotropy of Fe 1/3 NbS 2 in the zigzag phase is reduced relative to stripe, consistent with the relative magnitudes of resistivity changes in experiment. Finally, our calculations reveal the likely directionality of the current-domain response, specifically, which domains are energetically stabilized for a given current direction.

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“…agrees with the experimental data in Ref. [38] for Fe intercalations likely corresponding to a-stripe and a-zigzag order.…”

supporting

confidence: 92%

Section: Discussionmentioning

confidence: 67%

Section: Resistivity Tensor and Switchingmentioning

confidence: 99%

Section: Resistivity Tensor and Switchingmentioning

confidence: 99%

mentioning

confidence: 99%

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Origins of anisotropic transport in the electrically switchable antiferromagnet Fe1/3NbS2

Weber

Neaton

2021

Phys. Rev. B

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Tunable High‐Temperature Tunneling Magnetoresistance in All‐van der Waals Antiferromagnet/Semiconductor/Ferromagnet Junctions

Jin,

Li,

Zhang

et al. 2024

Adv Funct Materials

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Magnetic tunnel junctions (MTJs) are widely applied in spintronic devices for efficient spin detection through the imbalance of spin polarization at the Fermi level. The van der Waals (vdW) property of 2D magnets with atomically flat surfaces and negligible surface roughness greatly facilitates the development of MTJs, primarily in ferromagnets. Here, A‐type antiferromagnetism in 2D vdW single‐crystal (Fe0.8Co0.2)3GaTe2 is reported with TN ≈ 203 K in bulk and ≈ 185 K in 9‐nm nanosheets. The metallic nature and out‐of‐plane magnetic anisotropy make it a suitable candidate for MTJ electrodes. By constructing heterostructures based on (Fe0.8Co0.2)3GaTe2/WSe2/Fe3GaTe2, a large tunneling magnetoresistance (TMR) ratio of 180% at low temperature is obtained, with the TMR signal persisting at near‐room temperature 280 K. Furthermore, the TMR is tunable by the electric field, and the MTJ device operates stably with a low applied bias down to 1 mV (≈0.6 nA), highlighting its potential for energy‐efficient spintronic devices. This work opens up new opportunities for 2D antiferromagnetic spintronics and quantum devices.

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Photonic‐Crafting of Non‐Volatile and Rewritable Antiferromagnetic Spin Textures with Drastic Difference in Electrical Conductivity

Kuo

Liou

et al. 2022

Advanced Materials

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Figure 3. Non-contact optical writing of the designed AFM pattern. a) Schematic of the designed pattern composed of the two distinct AFM configurations written by laser illumination. b) The XAS spectra mapping taken by measuring I A /I B , where the I A(B) is the intensity of the spectra taken at the energy A(B) for E//b as marked in Figure 3c and Figure 3d. c,d) The XAS polarization-dependent spectra for E//a and E//b taken at point 1 inside the word "BFO" (c) and at point 2 outside the word "BFO" (d)

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Antiferromagnetic switching driven by the collective dynamics of a coexisting spin glass

Cited by 38 publications

References 33 publications

Origins of anisotropic transport in the electrically switchable antiferromagnet Fe1/3NbS2

Origins of anisotropic transport in the electrically switchable antiferromagnet Fe1/3NbS2

Tunable High‐Temperature Tunneling Magnetoresistance in All‐van der Waals Antiferromagnet/Semiconductor/Ferromagnet Junctions

Photonic‐Crafting of Non‐Volatile and Rewritable Antiferromagnetic Spin Textures with Drastic Difference in Electrical Conductivity

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