Valley-Coupled-Spintronic Non-Volatile Memories with Compute-In-Memory Support

TL;DR

This paper introduces valley-coupled spintronic MRAMs based on monolayer WSe2, demonstrating improved energy efficiency and integrated compute-in-memory capabilities for logic operations and system-level applications.

Contribution

It proposes a novel valley-coupled spin-Hall memory design with gate control, experimental validation, and system-level evaluation showing significant energy savings and in-memory computation features.

Findings

50% lower write time compared to GSH-MRAMs

Up to 3.14X energy efficiency improvement in system applications

DVSH-MRAM enables in-memory logic and addition operations

Abstract

In this work, we propose valley-coupled spin-hall memories (VSH-MRAMs) based on monolayer WSe2. The key features of the proposed memories are (a) the ability to switch magnets with perpendicular magnetic anisotropy (PMA) via VSH effect and (b) an integrated gate that can modulate the charge/spin current (IC/IS) flow. The former attribute results in high energy efficiency (compared to the Giant-Spin Hall (GSH) effect-based devices with in-plane magnetic anisotropy (IMA) magnets). The latter feature leads to a compact access transistor-less memory array design. We experimentally measure the gate controllability of the current as well as the nonlocal resistance associated with VSH effect. Based on the measured data, we develop a simulation framework (using physical equations) to propose and analyze single-ended and differential VSH effect based magnetic memories (VSH-MRAM and DVSH-MRAM, respectively). At the array level, the proposed VSH/DVSH-MRAMs achieve 50%/ 11% lower write time, 59%/ 67% lower write energy and 35%/ 41% lower read energy at iso-sense margin, compared to single ended/differential (GSH/DGSH)-MRAMs. System level evaluation in the context of general purpose processor and intermittently-powered system shows up to 3.14X and 1.98X better energy efficiency for the proposed (D)VSH-MRAMs over (D)GSH-MRAMs respectively. Further, the differential sensing of the proposed DVSH-MRAM leads to natural and simultaneous in-memory computation of bit-wise AND and NOR logic functions. Using this feature, we design a computation-in-memory (CiM) architecture that performs Boolean logic and addition (ADD) with a single array access. System analysis performed by integrating our DVSH-MRAM: CiM in the Nios II processor across various application benchmarks shows up to 2.66X total energy savings, compared to DGSH-MRAM: CiM.