Issue 34, 2024

Harnessing a WOx-based flexible transparent memristor synapse with a hafnium oxide layer for neuromorphic computing

Abstract

Transparent memristor-based neuromorphic synapses are expected to be specialised devices for high-speed information transmission and processing. The synaptic linearity and potentiation/depression cycles are imperative issues for the application of memristors. This work explores a memristor for improving switching uniformity by introducing a thin HfOx interfacial layer as a diffusion-limiting layer sandwiched between WOx and ITO bottom electrodes. An optimized HfOx thickness not only provides the best switching properties but also shows superior synaptic properties. The optimized 15 nm thin WOx layer can retain the memristor's excellence in P/D linearity, a cycling stability of 494 epochs and image recognition up to 3 mm bending, making it suitable for flexible devices. The artificial synapse is capable of reversible short-term and long-term learning behaviors confirmed by spike-timing-dependent-plasticity (STDP) results. X-ray photoelectron spectroscopy confirms the device composition and provides the oxygen vacancy concentration at the WOx/HfOx interface to realize the switching mechanism. The thicknesses of the different layers are estimated from the high-resolution transmission electron microscopy observations. The fabricated device exhibits 92.2% transparency, as confirmed by the UV-Vis spectrum.

Graphical abstract: Harnessing a WOx-based flexible transparent memristor synapse with a hafnium oxide layer for neuromorphic computing

Article information

Article type
Paper
Submitted
17 Mar 2024
Accepted
23 Jul 2024
First published
25 Jul 2024

Nanoscale, 2024,16, 16148-16158

Harnessing a WOx-based flexible transparent memristor synapse with a hafnium oxide layer for neuromorphic computing

D. Panda, Y. Hui and T. Tseng, Nanoscale, 2024, 16, 16148 DOI: 10.1039/D4NR01155D

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