Modeling and Design Space Exploration for Bit-Cells Based on Voltage-Assisted Switching of Magnetic Tunnel Junctions

Abstract

The effect of voltage on the anisotropy of a magnetic tunnel junction (MTJ) is of substantial interest for low-power nonvolatile memory applications. In this paper, we develop a device-to-bit-cell level simulation framework for voltage-assisted switching of the MTJs, which can satisfactorily reproduce the published experimental data. Our simulation framework is based on a coupled Landau–Lifshitz–Gilbert–Slonczewski equation and nonequilibrium greens function formalism. Using this simulation framework, we investigate the effect of scaling the oxide thickness of an MTJ to enhance the electric field effect. Although it seems attractive for an isolated device, yet, in a bit-cell configuration, reducing the oxide thickness leads to an increase in the supply voltage. In addition, we demonstrate that the unipolar characteristic of the voltage-assisted switching leads to write failures depending on the initial state stored in the MTJ. We, therefore, suggest a read before write scheme exhibiting approximately $2\times $ improvement in the write energy consumption at a bit-cell level compared with a standard STT-MRAM for iso-oxide thickness. However, the latency overhead associated with voltage-assisted MTJs results in a $1.55\times $ degradation of the write speed. Moreover, our layout analysis indicates that the bit-cell area reduction is constrained by the metal pitch, in spite of smaller access transistors.