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Magnetoresistive Random Access Memory: Present and Future

S. Ikegawa, F. B. Mancoff, J. Janesky, S. Aggarwal

2020IEEE Transactions on Electron Devices248 citationsDOI

Abstract

Magnetoresistive random access memory (MRAM) is regarded as a reliable persistent memory technology because of its long data retention and robust endurance. Initial MRAM products utilized toggle mode writing of a balanced synthetic antiferromagnet (SAF) free layer to overcome problems with half-selected bits that challenged traditional Stoner-Wohlfarth switching. With the development of spin transfer torque (STT) switching in perpendicular magnetic tunnel junctions, the capability for scaling MRAM products increased markedly, enabling a 1-Gb device in 2019. Ongoing research will allow scaling to even higher capacities. Compared to traditional memories, STT-MRAM can save power, improve performance, and enhance system data integrity, which supports the growing computing demands for everything from data centers to Internet of Things (IoT) devices. This article provides a review of the technology that enabled present toggle and STT-MRAM products, future STT-MRAM products, and new MRAM technologies beyond STT.

Topics & Concepts

Magnetoresistive random-access memoryTunnel magnetoresistanceMagnetoresistanceComputer scienceScalingSpin-transfer torqueRandom access memoryMagnetic storageElectrical engineeringTorqueNon-volatile memoryPower (physics)Electronic engineeringEngineeringMaterials scienceComputer hardwareLayer (electronics)PhysicsNanotechnologyMagnetic fieldMagnetizationOperating systemMathematicsGeometryThermodynamicsQuantum mechanicsMagnetic properties of thin filmsAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance Devices
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