High-Resolution Full-field Structural Microscopy of the Voltage Induced Filament Formation in Neuromorphic Devices

TL;DR

This study employs Dark Field X-ray Microscopy to visualize and analyze the structural dynamics of filament formation in VO2 memristive devices during electrical switching, revealing nucleation sites and phase coexistence.

Contribution

It introduces a full-field, in-operando structural imaging technique to study filament formation in VO2, uncovering nucleation pathways and phase coexistence with high spatial resolution.

Findings

Filament formation follows a preferential path determined by nucleation sites.

Pre-formation metallic rutile phase appears beneath electrodes.

Presence of low-temperature phase clusters inside high-temperature filaments.

Abstract

Neuromorphic functionalities in memristive devices are commonly associated with the ability to electrically create local conductive pathways by resistive switching. The archetypal correlated material, VO2, has been intensively studied for its complex electronic and structural phase transition as well as its filament formation under applied voltages. Local structural studies of the filament behavior are often limited due to time-consuming rastering which makes impractical many experiments aimed at investigating large spatial areas or temporal dynamics associated with the electrical triggering of the phase transition. Utilizing Dark Field X-ray Microscopy (DFXM), a novel full-field x-ray imaging technique, we study this complex filament formation process in-operando in VO2 devices from a structural perspective. We show that prior to filament formation, there is a significant gain of the metallic rutile phase beneath the metal electrodes that define the device. We observed that the filament formation follows a preferential path determined by the nucleation sites within the device. These nucleation sites are predisposed to the phase transition and can persistently maintain the high-temperature rutile phase even after returning to room temperature, which can enable a novel training/learning mechanism. Filament formation also appears to follow a preferential path determined by a nucleation site within the device which is predisposed to the rutile transition even after returning to room temperature. Finally, we found that small isolated low-temperature phase clusters can be present inside the high-temperature filaments indicating that the filament structure is not uniform. Our results provide a unique perspective on the electrically induced filament formation in metal-insulator transition materials, which further the basic understanding of this resistive switching.