Field-free spin–orbit-torque switching of perpendicular magnetization aided by uniaxial shape anisotropy

Wang, Zhaohao; Li, Zuwei; Wang, Min; Wu, Bi; Zhu, Daoqian; Zhao, Weisheng

doi:10.1088/1361-6528/ab2831

Cited by 32 publications

(18 citation statements)

References 68 publications

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“…Other manifestations of hybrid ME-SOT heterostructures have been explored to break critical symmetries and lift degeneracies in SOT switching [229][230][231][232]. For instance, SOT switching of a perpendicular magnetic anisotropy (PMA) magnet by the spin Hall effect of isotropic heavy metals is complicated by non-deterministic switching.…”

Section: Hybrid Magnetoelectric-spin-orbit Torque Heterostructuresmentioning

confidence: 99%

Multiferroic heterostructures for spintronics

Gradauskaite

Meisenheimer

Müller

et al. 2020

Physical Sciences Reviews

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For next-generation technology, magnetic systems are of interest due to the natural ability to store information and, through spin transport, propagate this information for logic functions. Controlling the magnetization state through currents has proven energy inefficient. Multiferroic thin-film heterostructures, combining ferroelectric and ferromagnetic orders, hold promise for energy efficient electronics. The electric field control of magnetic order is expected to reduce energy dissipation by 2–3 orders of magnitude relative to the current state-of-the-art. The coupling between electrical and magnetic orders in multiferroic and magnetoelectric thin-film heterostructures relies on interfacial coupling though magnetic exchange or mechanical strain and the correlation between domains in adjacent functional ferroic layers. We review the recent developments in electrical control of magnetism through artificial magnetoelectric heterostructures, domain imprint, emergent physics and device paradigms for magnetoelectric logic, neuromorphic devices, and hybrid magnetoelectric/spin-current-based applications. Finally, we conclude with a discussion of experiments that probe the crucial dynamics of the magnetoelectric switching and optical tuning of ferroelectric states towards all-optical control of magnetoelectric switching events.

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Section: Hybrid Magnetoelectric-spin-orbit Torque Heterostructuresmentioning

confidence: 99%

Multiferroic heterostructures for spintronics

Gradauskaite

Meisenheimer

Müller

et al. 2020

Physical Sciences Reviews

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“…When a current crosses the non-magnetic layer, spins are accumulated and a torque switching is generated over the magnetization of the ferromagnetic layer. A faster switching can occur using SOT with the elimination of the time-demanding precessional motion [28]. However, one disadvantage of SOT is that it requires bigger cell size than STT-based applications due to its three terminal structure, so it can be not compatible with high-density applications.…”

Section: Spin-orbit Torque (Sot)mentioning

confidence: 99%

Magnetic Tunnel Junction Applications

Maciel

Marques

Naviner

et al. 2019

Sensors

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Spin-based devices can reduce energy leakage and thus increase energy efficiency. They have been seen as an approach to overcoming the constraints of CMOS downscaling, specifically, the Magnetic Tunnel Junction (MTJ) which has been the focus of much research in recent years. Its nonvolatility, scalability and low power consumption are highly attractive when applied in several components. This paper aims at providing a survey of a selection of MTJ applications such as memory and analog to digital converter, among others.

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“…Because the spin orbit torque exerted on the electron spin in the FM layer was related to the current density of the NM layer, manipulation of the magnetization direction of the FM layer would be dependent on its position on the NM layer. It has been reported that specific patterning of both FM layer and NM layer could be utilized to control the magnetization state of the FM layer [Safeer 2016, Siddiqui 2020, Martinez 2016, Wang 2019]. Hence, the feasibility of applying such method in spinbased data storage has been confirmed.…”

Section: Introductionmentioning

confidence: 99%

Nonvolatile Magnetic Memory Combined With AND/NAND Boolean Logic Gates Based on Geometry-Controlled Magnetization Switching

Xiong

Mou

et al. 2021

IEEE Magn. Lett.

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Spin-orbit torque(SOT) has been widely used in data writing of spintronic memory devices by currentinduced magnetization switching. The typical structure of SOT-induced magnetization switching of ferromagnetic multilayers with perpendicular magnetic anisotropy(PMA) such as Ta/CoFeB/MgO allowed the ferromagnetic and adjacent nonmagnetic layer to be patterned independently. Here, we studied the role of device geometry in the manipulation of magnetization switching by placing two separated CoFeB magnetic bits at different locations on Ta layer with trapezoid shape. Manipulation of the magnetization states of the magnetic bits was achieved simply by applying different write current. Both memory writing and Boolean logic functions AND/NAND with large logic output ratio have been demonstrated experimentally.

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Field-free spin–orbit-torque switching of perpendicular magnetization aided by uniaxial shape anisotropy

Cited by 32 publications

References 68 publications

Multiferroic heterostructures for spintronics

Multiferroic heterostructures for spintronics

Magnetic Tunnel Junction Applications

Nonvolatile Magnetic Memory Combined With AND/NAND Boolean Logic Gates Based on Geometry-Controlled Magnetization Switching

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