Programmable spin–orbit-torque logic device with integrated bipolar bias field for chirality control

Driven by the need to address both the von Neumann bottleneck and scaling limits predicted by Moore's law, spintronic devices have been shown to be strong contenders for logic-in-memory applications. While several field-free spin–orbit torque (SOT)-driven logic devices have been proposed, their...

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Bibliographic Details
Main Authors: Lim, Gerard Joseph, Chua Daniel, Gan Weiliang, Murapaka Chandrasekhar, Lew Wen Siang
Other Authors: School of Physical and Mathematical Sciences
Format: Article
Language:English
Published: 2021
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Online Access:https://hdl.handle.net/10356/154221
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Institution: Nanyang Technological University
Language: English
Description
Summary:Driven by the need to address both the von Neumann bottleneck and scaling limits predicted by Moore's law, spintronic devices have been shown to be strong contenders for logic-in-memory applications. While several field-free spin–orbit torque (SOT)-driven logic devices have been proposed, their operation typically requires additional initialization or reset pulses, the exchange-coupled canted spins reduce both anomalous Hall sign-to-noise ratio as well as thermal stability of the ferromagnetic layer, and device-to-device variation in exchange coupling strength is expected. A reconfigurable SOT-driven logic device using a double Hall cross structure with an integrated bias field line for the generation of a local bias field is experimentally demonstrated. The on-chip bipolar bias field can be toggled to flip the SOT-induced switching chirality, and to assist with deterministic SOT magnetization switching, thereby enabling on-the-fly reconfigurability of the logic device to function as one of the several possible logic gates, e.g., AND, NOR, XNOR, XOR, NIMP, and converse NIMP. It is then shown through compact-modeling and circuit simulation that the applications of such reconfigurable logic devices can be further expanded to build half-adders.