On the area scalability of valence-change memristors for neuromorphic computing
The ability to vary the conductance of a valence-change memristor in a continuous manner makes it a prime choice as an artificial synapse in neuromorphic systems. Because synapses are the most numerous components in the brain, exceeding the neurons by several orders of magnitude, the scalability of...
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sg-ntu-dr.10356-1431532020-08-05T08:47:20Z On the area scalability of valence-change memristors for neuromorphic computing Ang, Diing Shenp Zhou, Yu Yew, Kwang Sing Berco, Dan School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Artificial Neural Networks Atomic Force Microscopy The ability to vary the conductance of a valence-change memristor in a continuous manner makes it a prime choice as an artificial synapse in neuromorphic systems. Because synapses are the most numerous components in the brain, exceeding the neurons by several orders of magnitude, the scalability of artificial synapses is crucial to the development of large scale neuromorphic systems but is an issue which is seldom investigated. Leveraging on the conductive atomic force microscopy method, we found that the conductance switching of nanoscale memristors (∼25 nm2) is abrupt in a majority of the cases examined. This behavior is contrary to the analoglike conductance modulation or plasticity typically observed in larger area memristors. The result therefore implies that plasticity may be lost when the device dimension is scaled down. The contributing factor behind the plasticity behavior of a large-area memristor was investigated by current mapping, and may be ascribed to the disruption of the plurality of conductive filaments happening at different voltages, thus yielding an apparent continuous change in conductance with voltage. The loss of plasticity in scaled memristors may pose a serious constraint to the development of large scale neuromorphic systems. Published version 2020-08-05T08:47:20Z 2020-08-05T08:47:20Z 2019 Journal Article Ang, D. S., Zhou, Y., Yew, K. S., & Berco, D. (2019). On the area scalability of valence-change memristors for neuromorphic computing. Applied Physics Letters, 115(17), 173501-. doi:10.1063/1.5116270 0003-6951 https://hdl.handle.net/10356/143153 10.1063/1.5116270 2-s2.0-85074089394 17 115 en Applied Physics Letters © 2019 Author(s). All rights reserved. This paper was published by AIP Publishing in Applied Physics Letters and is made available with permission of Author(s). application/pdf |
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Engineering::Electrical and electronic engineering Artificial Neural Networks Atomic Force Microscopy Ang, Diing Shenp Zhou, Yu Yew, Kwang Sing Berco, Dan On the area scalability of valence-change memristors for neuromorphic computing |
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The ability to vary the conductance of a valence-change memristor in a continuous manner makes it a prime choice as an artificial synapse in neuromorphic systems. Because synapses are the most numerous components in the brain, exceeding the neurons by several orders of magnitude, the scalability of artificial synapses is crucial to the development of large scale neuromorphic systems but is an issue which is seldom investigated. Leveraging on the conductive atomic force microscopy method, we found that the conductance switching of nanoscale memristors (∼25 nm2) is abrupt in a majority of the cases examined. This behavior is contrary to the analoglike conductance modulation or plasticity typically observed in larger area memristors. The result therefore implies that plasticity may be lost when the device dimension is scaled down. The contributing factor behind the plasticity behavior of a large-area memristor was investigated by current mapping, and may be ascribed to the disruption of the plurality of conductive filaments happening at different voltages, thus yielding an apparent continuous change in conductance with voltage. The loss of plasticity in scaled memristors may pose a serious constraint to the development of large scale neuromorphic systems. |
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School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Ang, Diing Shenp Zhou, Yu Yew, Kwang Sing Berco, Dan |
| format |
Article |
| author |
Ang, Diing Shenp Zhou, Yu Yew, Kwang Sing Berco, Dan |
| author_sort |
Ang, Diing Shenp |
| title |
On the area scalability of valence-change memristors for neuromorphic computing |
| title_short |
On the area scalability of valence-change memristors for neuromorphic computing |
| title_full |
On the area scalability of valence-change memristors for neuromorphic computing |
| title_fullStr |
On the area scalability of valence-change memristors for neuromorphic computing |
| title_full_unstemmed |
On the area scalability of valence-change memristors for neuromorphic computing |
| title_sort |
on the area scalability of valence-change memristors for neuromorphic computing |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143153 |
| _version_ |
1681057573818597376 |