Enhancement of spin–orbit torque in Pt/Co/HfOx heterostructures with voltage-controlled oxygen ion migration

Wu, S.; Jin, Tianli; Tan, Funan; Ang, Calvin Ching Ian; Poh, H. Y.; Lim, Gerard Joseph; Lew, Wen Siang

doi:10.1063/5.0139443

Cited by 8 publications

(5 citation statements)

References 38 publications

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“…Recently, Yang et al reported the field-free magnetization switching by PtTe 2 /WTe 2 with very high spin Hall conductivity . Meanwhile, various methods have been explored to improve the efficiency of SOT, such as light modulation, electric field modulation, and alloying. There have been extensive studies on methods to increase the magnitude of the spin Hall angle by adding nonmagnetic impurities to heavy metal materials, such as Pt doped with Au, Bi, Cu, and Pd .…”

Section: Introductionmentioning

confidence: 99%

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Qu,

Xu,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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Spin−orbit torque (SOT) has emerged as an effective means of manipulating magnetization. However, the current energy efficiency of SOT operation is inefficient due to low damping-like SOT efficiency per unit current bias. In this work, we dope conventional rare earth oxides, GdO y , into highly conductive platinum by magnetron sputtering to form a new group of spin Hall materials. A large damping-like spin−orbit torque (DL-SOT) efficiency of about 0.35 ± 0.013 is obtained in Pt 0.70 (GdO y ) 0.30 measured by the spin-torque ferromagnetic resonance (ST-FMR) technique, which is about five times that of pure Pt under the same conditions. The substantial enhancement of the spin Hall effect is revealed by theoretical analysis to be attributed to the strong side jump induced by the rare earth oxide GdO y impurities. Moreover, this large DL-SOT efficiency contributes to a low critical switching current density (8.0 × 10 6 A•cm −2 in the Pt 0.70 (GdO y ) 0.30 layer) in current-induced magnetization switching measurements. This systematic study on SOT switching properties suggests that Pt 1−x (GdO y ) x is an attractive spin current source with large DL-SOT efficiency for future SOT applications and provides another idea to regulate the spin Hall angle.

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Section: Introductionmentioning

confidence: 99%

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Qu,

Xu,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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“…This gate-voltage-induced oxidation process offers a promising way to manipulate interfacial properties and, consequently, modulate SOT efficiency in a controllable and reversible manner. Notably, voltage control of SOT has been demonstrated in various systems, such as the Pt/Co system [20,21], a Crdoped topological insulator [22], and using ionic liquid [12,23]. Previous works [24][25][26] primarily utilized electric fields to influence interfacial oxidation in voltage-controlled magnetism within ferromagnetic/oxide systems, thereby facilitating magnetization switching through changes in magnetic properties.…”

Section: Introductionmentioning

confidence: 99%

Electric field control of spin-orbit torque in annealed Ta/CoFeB/HfO _x heterostructures via interfacial oxidation modulation

Wu,

Jin,

Ang

et al. 2024

Nanotechnology

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Electric field control of spin-orbit torque (SOT) exhibits promising potential in advanced spintronic devices through interfacial modulation. In this work, we investigate the influence of electric field and interfacial oxidation on SOT efficiency in annealed Ta/CoFeB/HfO x heterostructures. By varying annealing temperatures, the damping-like SOT efficiency reaches its peak at the annealing temperature of 320 °C, with an 80% field-free magnetization switching ratio induced by SOT having been demonstrated. This enhancement is ascribed to the annealing-induced modulation of oxygen ion migration at the CoFeB/HfO x interface. By applying voltages across the Ta/CoFeB/HfO x heterostructures, which drives the O2‒ migration across the interface, a reversible, bipolar, and non-volatile modulation of SOT efficiency was observed. The collective influence of annealing temperature and electric field effects on SOT carried out in this work provides an effective approach into facilitating the optimization and control of SOT in spintronic devices.

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“…In the Pt/Co/Ti sample, a pulsed field of −40 Oe is applied, resulting in the nucleation of a dark domain at one boundary, which subsequently grows larger with the continuous application of the same pulsed field. The DW motion leads to the sharp switching as observed in the M – H oop loop in the Pt/Co/Ti sample. − However, granular magnetization switching is observed in the Pt/Co/HfOx/Ti sample, as revealed by Kerr imaging. The number of nucleated dark domains rapidly increases with the continuous application of the pulsed field instead of undergoing magnetization reversal via DW motion.…”

mentioning

confidence: 99%

“…In both cases, H DL with J ac exhibits good linearity. 31 To comprise the SOT efficiency, the damping-like field efficiency χ of two stacks is extracted, where χ is defined as H DL /J ac . The χ DL increases from 9.1 to 11.5 Oe/(10 10 A/m 2 ) with the addition of the HfOx insertion layer.…”

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confidence: 99%

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Granular Magnetization Switching in Pt/Co/Ti Structure with HfOx Insertion for In-Memory Computing Applications

Jin,

Zhang,

Tan

et al. 2024

Nano Lett.

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Exploring multiple states based on the domain wall (DW) position has garnered increased attention for in-memory computing applications, particularly focusing on the utilization of spin−orbit torque (SOT) to drive DW motion. However, devices relying on the DW position require efficient DW pinning. Here, we achieve granular magnetization switching by incorporating an HfOx insertion layer between the Co/Ti interface. This corresponds to a transition in the switching model from the DW motion to DW nucleation. Compared to the conventional Pt/Co/Ti structure, incorporation of the HfOx layer results in an enhanced SOT efficiency and a lower switching current density. We also realized stable multistate storage and synaptic plasticity by applying pulse current in the Pt/Co/HfOx/Ti device. The simulation of artificial neural networks (ANN) based on the device can perform digital recognition tasks with an accuracy rate of 91%. These results identify that DW nucleation with a Pt/Co/HfOx/Ti based device has potential applications in multistate storage and ANN.

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Enhancement of spin–orbit torque in Pt/Co/HfOx heterostructures with voltage-controlled oxygen ion migration

Cited by 8 publications

References 38 publications

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Electric field control of spin-orbit torque in annealed Ta/CoFeB/HfO _x heterostructures via interfacial oxidation modulation

Granular Magnetization Switching in Pt/Co/Ti Structure with HfOx Insertion for In-Memory Computing Applications

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Enhancement of spin–orbit torque in Pt/Co/HfOx heterostructures with voltage-controlled oxygen ion migration

Cited by 8 publications

References 38 publications

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Enhanced Spin–Orbit Torque Efficiency in Platinum–Gadolinium Oxide Nanocomposite Films

Electric field control of spin-orbit torque in annealed Ta/CoFeB/HfO x heterostructures via interfacial oxidation modulation

Granular Magnetization Switching in Pt/Co/Ti Structure with HfOx Insertion for In-Memory Computing Applications

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Electric field control of spin-orbit torque in annealed Ta/CoFeB/HfO _x heterostructures via interfacial oxidation modulation