Litcius/Paper detail

SOT and STT-Based 4-Bit MRAM Cell for High-Density Memory Applications

Arshid Nisar, Seema Dhull, Sparsh Mittal, Brajesh Kumar Kaushik

2021IEEE Transactions on Electron Devices30 citationsDOI

Abstract

This article presents a multilevel design for spin-orbit torque (SOT)-assisted spin-transfer torque (STT)-based 4-bit magnetic random access memory (MRAM). Multilevel cell (MLC) design is an effective solution to increase the storage capacity of MRAM. The conventional SOT-MRAMs enable an energy-efficient, fast, and reliable write operation. However, unlike STT-MRAM, these cells take more area and require two access transistors per cell. This poses significant challenges in the use of SOT-MRAMs for high-density memory applications. To address these issues, we propose an MLC that can store 4 bits and requires only three access transistors. The effective area per bit of the proposed cell is nearly 58% lower than that of the conventional 1-bit SOT-MRAM cell. The combined effect of SOT and STT has been incorporated to design SOT-STT-based MLC that enables more energy-efficient and faster write operation than the regular MLCs. The results show that SOT-STT-based 4-bit MLC is 52.9% and 40% more efficient in terms of latency and energy consumption, respectively, when compared to 3-bit SOT-/STT-based MLC.

Topics & Concepts

Magnetoresistive random-access memoryComputer scienceSpin-transfer torqueEfficient energy useRacetrack memoryRandom access memoryBit (key)TransistorEnergy consumptionElectronic engineeringElectrical engineeringComputer hardwareEmbedded systemSemiconductor memoryEngineeringComputer memoryMemory refreshVoltagePhysicsComputer networkMagnetizationMagnetic fieldQuantum mechanicsMagnetic properties of thin filmsAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance Devices