Multilevel Spin-Orbit Torque MRAMs

Author

Yusung Kim ; Xuanyao Fong ; Kon-Woo Kwon ; Mei-Chin Chen ; Roy, Kaushik

Author_Institution

Sch. of Electr. & Comput. Eng., Purdue Univ., West Lafayette, IN, USA

Volume

62

Issue

2

fYear

2015

fDate

Feb. 2015

Firstpage

561

Lastpage

568

Abstract

In this paper, we present two multilevel spin-orbit torque magnetic random access memories (SOT-MRAMs). A single-level SOT-MRAM employs a three-terminal SOT device as a storage element with enhanced endurance, close-to-zero read disturbance, and low write energy. However, the three-terminal device requires the use of two access transistors per cell. To improve the integration density, we propose two multilevel cells (MLCs): 1) series SOT MLC and 2) parallel SOT MLC, both of which store two bits per memory cell. A detailed analysis of the bit-cell suggests that the S-MLC is promising for applications requiring both high density and low write-error rate, and P-MLC is particularly suitable for high-density and low-write-energy applications. We also performed iso-bit-cell area comparison of our MLC designs with previously proposed MLCs that are based on spin-transfer torque MRAM and show 3-16× improvement in write energy.

Keywords

MRAM devices; error statistics; spin-orbit interactions; SOT device; SOT-MRAM; access transistors; close-to-zero read disturbance; enhanced endurance; iso-bit-cell area; magnetic random access memories; multilevel spin orbit torque; storage element; write error rate; Frequency modulation; Integrated circuits; Layout; Magnetic tunneling; Optimization; Resistance; Torque; Magnetic memory; multilevel cell (MLC); spin-Hall effect (SHE); spin-orbit torque (SOT); spin-transfer torque (STT); spin-transfer torque (STT).;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2014.2377721

Filename

6991544