Nanoscale metal oxide memristors have potential in the development of brain-inspired computing systems that are scalable and efficient1-3. In such systems, memristors represent the native electronic analogues of the biological synapses. However, the characteristics of the existing memristors do not fully support the key requirements of synaptic connections: high density, adjustable weight, and low energy operation. Here we show a bilayer memristor that is forming-free, low-voltage (~|0.8V|), energy-efficient (full On/Off switching at ~2pJ), and reliable. Furthermore, pulse measurements reveal the analog nature of the memristive device, that is it can be directly programmed to intermediate resistance states. Leveraging this finding, we demonstrate spike-timing-dependent plasticity (STDP), a spike-based Hebbian learning rule4. In those experiments, the memristor exhibits a marked change in the normalized synaptic strength (>30 times) when the pre- and post-synaptic neural spikes overlap. This demonstration is an important step towards the physical construction of high density and high connectivity neural networks.
@article{arxiv.1603.03979,
title = {A sub-1-volt analog metal oxide memristive-based synaptic device for energy-efficient spike-based computing systems},
author = {Cheng-Chih Hsieh and Anupam Roy and Yao-Feng Chang and Davood Shahrjerdi and Sanjay K. Banerjee},
journal= {arXiv preprint arXiv:1603.03979},
year = {2016}
}
Comments
11 pages of main text, 3 pages of supplementary information, 5 figures, submitted for Advanced Materials