IEEE Journal on Exploratory Solid-State Computational Devices and Circuits (Jan 2019)

Modeling and Circuit Design of Associative Memories With Spin–Orbit Torque FETs

  • Olalekan Afuye,
  • Xiang Li,
  • Felicia Guo,
  • Debdeep Jena,
  • Daniel C. Ralph,
  • Alyosha Molnar,
  • Huili Grace Xing,
  • Alyssa Apsel

DOI
https://doi.org/10.1109/JXCDC.2019.2952394
Journal volume & issue
Vol. 5, no. 2
pp. 197 – 205

Abstract

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This article introduces a circuits model for a proposed spin-based device called a spin-orbit torque field-effect transistor (SOTFET) that can operate as a nonvolatile memory and logic device. The SOTFET utilizes an FET structure with a ferromagnetic-multiferroic (MF) gate-stack that enables read/compute and write functions to be isolated. This is achieved by a combination of a ferromagnetic layer that is programmable via spin-orbit torque coupled to an MF layer that also couples into the gate of a traditional FET. Additionally, this device has logic gate-like behavior and can be designed to operate in either AND or OR gate mode. We begin with a physics-based model of this device and derive a SPICE level model that can be integrated into the Cadence toolset. Using such a device we demonstrate MRAM, content addressable memories (CAM), and ternary CAM (TCAM) functionality with 3 to 5 transistors, a significant decrease over the CMOS alternative circuits, showing that such a device can enable low cost and compact associative memories not currently feasible with CMOS devices.

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