Sensory gating in bilayer amorphous carbon memristors

T. J. Raeber; A. J. Barlow; Z. C. Zhao; D. R. McKenzie; J. G. Partridge; D. G. McCulloch; B. J. Murdoch

doi:10.1039/c8nr05328f

Sensory gating in bilayer amorphous carbon memristors

T. J. Raeber, A. J. Barlow, Z. C. Zhao, D. R. McKenzie, J. G. Partridge, D. G. McCulloch, B. J. Murdoch

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

Multi-state amorphous carbon-based memory devices have been developed that exhibit both bipolar and unipolar resistive switching behaviour. These modes of operation were implemented independently to access multiple resistance states, enabling higher memory density than conventional binary non-volatile memory technologies. The switching characteristics have been further utilised to study synaptic computational functions that could be implemented in artificial neural networks. Notably, paired-pulse inhibition (PPI) is observed at bio-realistic timescales (<100 ms). Devices displaying this rich synaptic behaviour could function as robust stand-alone synapse-inspired memory or be applied as filters for specialised neuromorphic circuits and sensors.

Original language	English
Pages (from-to)	20272-20278
Number of pages	7
Journal	Nanoscale
Volume	10
Issue number	43
DOIs	https://doi.org/10.1039/c8nr05328f
Publication status	Published - 21 Nov 2018
Externally published	Yes

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title = "Sensory gating in bilayer amorphous carbon memristors",

abstract = "Multi-state amorphous carbon-based memory devices have been developed that exhibit both bipolar and unipolar resistive switching behaviour. These modes of operation were implemented independently to access multiple resistance states, enabling higher memory density than conventional binary non-volatile memory technologies. The switching characteristics have been further utilised to study synaptic computational functions that could be implemented in artificial neural networks. Notably, paired-pulse inhibition (PPI) is observed at bio-realistic timescales (<100 ms). Devices displaying this rich synaptic behaviour could function as robust stand-alone synapse-inspired memory or be applied as filters for specialised neuromorphic circuits and sensors.",

author = "Raeber, \{T. J.\} and Barlow, \{A. J.\} and Zhao, \{Z. C.\} and McKenzie, \{D. R.\} and Partridge, \{J. G.\} and McCulloch, \{D. G.\} and Murdoch, \{B. J.\}",

year = "2018",

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AU - Raeber, T. J.

AU - Barlow, A. J.

AU - Zhao, Z. C.

AU - McKenzie, D. R.

AU - Partridge, J. G.

AU - McCulloch, D. G.

AU - Murdoch, B. J.

PY - 2018/11/21

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AB - Multi-state amorphous carbon-based memory devices have been developed that exhibit both bipolar and unipolar resistive switching behaviour. These modes of operation were implemented independently to access multiple resistance states, enabling higher memory density than conventional binary non-volatile memory technologies. The switching characteristics have been further utilised to study synaptic computational functions that could be implemented in artificial neural networks. Notably, paired-pulse inhibition (PPI) is observed at bio-realistic timescales (<100 ms). Devices displaying this rich synaptic behaviour could function as robust stand-alone synapse-inspired memory or be applied as filters for specialised neuromorphic circuits and sensors.

UR - https://www.scopus.com/pages/publications/85056323832

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SP - 20272

EP - 20278

JO - Nanoscale

JF - Nanoscale

IS - 43

ER -

Sensory gating in bilayer amorphous carbon memristors

Abstract

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