Vacuum and Low-Temperature Characteristics of Silicon Oxynitride-Based Bipolar RRAM.

This study investigates the switching characteristics of the silicon oxynitride (SiO x N y )-based bipolar resistive random-access memory (RRAM) devices at different operating ambiances at temperatures ranging from 300 K to 77 K. The operating ambiances (open air or vacuum) and temperature affect the device's performance. The electroforming-free multilevel bipolar Au/Ni/SiO x N y /p + -Si RRAM device (in open-air) becomes bilevel in a vacuum with an on/off ratio >10 4 and promising data retention properties. The device becomes more resistive with cryogenic temperatures. The experimental results indicate that the presence and absence of moisture (hydrogen and hydroxyl groups) in open air and vacuum, respectively, alter the elemental composition of the amorphous SiO x N y active layer and Ni/SiO x N y interface region. Consequently, this affects the overall device performance. Filament-type resistive switching and trap-controlled space charge limited conduction (SCLC) mechanisms in the bulk SiO x N y layer are confirmed.