Two-dimensional (2D) materials have attracted much attention as the active medium in memristors for next generation computing hardware solutions like in-memory computing or neuromorphic computing. Hexagonal boron nitride (h-BN) is particularly promising due to its insulating property which enables low stand-by currents and a large switching window. Volatile (threshold) resistive switching in h-BN devices is of specific interest for certain synaptic/neuronal functions in neuromorphic circuits and is useful for selectors in crossbar arrays. Here we present a complementary metal-oxide semiconductor technology (CMOS) compatible, multilayer h-BN based threshold memristor with a wide and tunable current operation range and low stand-by currents. The switching characteristics of our devices are comparable to other h-BN based threshold switches in literature. In addition, our results show a low cycle-to-cycle variability of 5%. We also provide a detailed study of the current conduction mechanism of our devices in the high and low resistance states by performing temperature-dependent current-voltage measurements. Supported by transmission electron microscopy analysis, we propose the formation and retraction of nickel-filaments along boron defects in the h-BN film as the resistive switching mechanism. Thus, we demonstrate that temperature-dependent current-voltage analysis is a valuable tool for analyzing resistive switching phenomena in 2D-material based memristors.
Published in: "arXiv Material Science".