Tunable Switching Mechanisms in HfZrO2-Based Tunnel Junctions for High-Performance Synaptic Arrays

초록

Strategic optimization of ferroelectric tunnel junctions (FTJs) is critical for advancing nonvolatile memory and neuromorphic computing technologies. In this work, we present a comprehensive study on materials and structural engineering to enable scalable hybrid-switching FTJ arrays. We systematically manipulated oxygen vacancy (V-O) concentrations in HfZrO2 (HZO) films through strategic choices of bottom electrodes and interfacial layers, achieving three distinct operational modes: pure ferroelectric switching, defect-modulated switching, and combined hybrid switching. Our optimized devices demonstrate exceptional tunneling electroresistance (TER) performance: Mo bottom electrodes achieve a TER ratio of around 10(2), while Mo/Ti bottom electrodes attain TER to over 10(4). Lower-leakage ferroelectric switching and enhanced polarization stability are observed with Mo bottom and ZrO2 interlayers, while V-O-driven resistive contributions from Ti electrodes amplify TER in hybrid devices. Utilizing these optimized parameters, we fabricated a 42 & times; 42 FTJ array demonstrating uniform multi-level conductance modulation. The fabricated FTJ array was integrated into an in-memory Vision Transformer (ViT) architecture, successfully performing stable and energy-efficient parallel vector-matrix multiplication (VMM) operations despite device variability. This work shows that precisely engineered, large-area hybrid-switching FTJ arrays can provide a scalable and energy-efficient hardware platform for next-generation memory and neuromorphic systems.

키워드