Resistive switching and role of interfaces in memristive devices based on amorphous NbOx grown by anodic oxidation

Memristive devices based on the resistive switching mechanism are continuously attracting attention in the framework of neuromorphic computing and next-generation memory devices. Here, we report on a comprehensive analysis of the resistive switching properties of amorphous NbOx grown by anodic oxidation. Besides a detailed chemical, structural and morphological analysis of the involved materials and interfaces, the mechanism of switching in Nb/NbOx/Au resistive switching cells is discussed by investigating the role of metal-metal oxide interfaces in regulating electronic and ionic transport mechanisms. The resistive switching was found to be related to the formation/rupture of conductive nanofilaments in the NbOx layer under the action of an applied electric field, facilitated by the presence of an oxygen scavenger layer at the Nb/NbOx interface. Electrical characterization including device-to-device variability revealed an endurance >10(3) full-sweep cycles, retention >10(4) s, and multilevel capabilities. Furthermore, the observation of quantized conductance supports the physical mechanism of switching based on the formation of atomic-scale conductive filaments. Besides providing new insights into the switching properties of NbOx, this work also highlights the perspective of anodic oxidation as a promising method for the realization of resistive switching cells.

Automated summary

This study provides a detailed analysis of the resistive switching properties of amorphous NbOx grown by anodic oxidation. The role of metal-metal oxide interfaces in regulating electronic and ionic transport mechanisms in Nb/NbOx/Au resistive switching cells is discussed. It is found that the resistive switching is related to the formation/rupture of conductive nanofilaments in the NbOx layer, facilitated by the presence of an oxygen scavenger layer at the Nb/NbOx interface. The electrical characterization shows durability, retention, and multilevel capabilities. The observation of quantized conductance supports the physical mechanism of atomic-scale conductive filaments formation.