Issue 7, 2022

Image processing with a multi-level ultra-fast three dimensionally integrated perovskite nanowire array

Abstract

Besides its ubiquitous applications in optoelectronics, halide-perovskites (HPs) have also carved a niche in the domain of resistive switching memories (Re-RAMs). However owing to the material and electrical instability challenges faced by HP thin-films, rarely perovskite Re-RAMs are used to experimentally demonstrate data processing which is a fundamental requirement for neuromorphic applications. Here, for the first time, lead-free, ultrahigh density HP nanowire (NW) array Re-RAM has been utilized to demonstrate image processing via design of convolutional kernels. The devices exhibited superior switching characteristics including a high endurance of 5 × 106 cycles, an ultra-fast erasing and writing speed of 900 ps and 2 ns, respectively, and a retention time >5 × 104 s for the resistances. The work is bolstered by an in-depth mechanistic study and first-principles simulations which provide evidence of electrochemical metallization triggering the switching. Employing the robust multi-level switching behaviour, image processing functions of embossing, outlining and sharpening were successfully implemented.

Graphical abstract: Image processing with a multi-level ultra-fast three dimensionally integrated perovskite nanowire array

Supplementary files

Article information

Article type
Communication
Submitted
06 Apr 2022
Accepted
17 May 2022
First published
23 May 2022

Nanoscale Horiz., 2022,7, 759-769

Image processing with a multi-level ultra-fast three dimensionally integrated perovskite nanowire array

S. Poddar, Y. Zhang, Z. Chen, Z. Ma, Y. Fu, Y. Ding, C. L. J. Chan, Q. Zhang, D. Zhang, Z. Song and Z. Fan, Nanoscale Horiz., 2022, 7, 759 DOI: 10.1039/D2NH00183G

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