Abstract

Racetrack memory with the advantages of small size and high reading speed is proposed based on current-induced domain wall (DW) motion in a ferromagnetic (FM) nanowire. Walker breakdown that restricts the enhancement of DW velocity in a single FM nanowire can be depressed by inter-wire magnetostatic coupling in a double FM nanowire system. However, this magnetostatic coupling also limits the working current density in a small range. In the present work, based on micromagnetic calculation, we have found that when there is a moderate difference of magnetic anisotropy constant between two FM nanowires, the critical current density for triggering the DW motion can be reduced while that for breaking the inter-wire coupling can be enhanced significantly to a magnitude of 1013 A m−2, which is far above the working current density in current electronic devices. The manipulation of working current density is relevant to the modification of DW structure and inter-wire magnetostatic coupling due to the difference of the anisotropy constants between the two nanowires and paves a way to develop racetrack memory that can work in a wide range of current.

Highlights

  • In racetrack memory that was proposed by Prof

  • Parkin in IBM in 20081, tDhOeI:d10ig.1i0ta39l /D1NA00540E information is stored in an array of magnetic domains in a nanowire of ferromagnetic metal (FM), and the domain wall (DW) that separates the neighboring domains are able to be driven by injecting an electrical current due to spin-transfer-torque (STT) effect[2,3,4]

  • The current induced DW motion (CIDWM) in an FM nanowire has been widely investigated in experiments and in theory[5,6,7,8,9,10,11,12]

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Summary

Introduction

In racetrack memory that was proposed by Prof. Parkin in IBM in 20081, tDhOeI:d10ig.1i0ta39l /D1NA00540E information is stored in an array of magnetic domains in a nanowire of ferromagnetic metal (FM), and the domain wall (DW) that separates the neighboring domains are able to be driven by injecting an electrical current due to spin-transfer-torque (STT) effect[2,3,4]. When compared to traditional hard disc driver, the racetrack memory device exhibits advantages of small size and high reading speed. The current induced DW motion (CIDWM) in an FM nanowire has been widely investigated in experiments and in theory[5,6,7,8,9,10,11,12]

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