Dataset in support of the journal article 'An ultra high-endurance memristor using back-end-of-line amorphous SiC'
Dataset in support of the journal article 'An ultra high-endurance memristor using back-end-of-line amorphous SiC'
Integrating resistive memory or neuromorphic memristors into mainstream silicon technology can be substantially facilitated if the memories are built in the back-end-of-line (BEOL) and stacked directly above the logic circuitries. Here we report a promising memristor employing a plasma-enhanced chemical vapour deposition (PECVD) bilayer of amorphous SiC/Si as device layer and Cu as an active electrode. Its endurance exceeds one billion cycles with an ON/OFF ratio of ca. two orders of magnitude. Resistance drift is observed in the first 200 million cycles, after which the devices settle with a coefficient of variation of ca. 10% for both the low and high resistance states. Ohmic conduction in the low resistance state is attributed to the formation of Cu conductive filaments inside the bilayer structure, where the nanoscale grain boundaries in the Si layer provide the pre-defined pathway for Cu ion migration. Rupture of the conductive filament leads to current conduction dominated by reverse bias Schottky emission. Multistate switching is achieved by precisely controlling the pulse conditions for potential neuromorphic computing applications. The PECVD deposition method employed here has been frequently used to deposit typical BEOL SiOC low-k interlayer dielectrics. This makes this a unique memristor system with great potential for integration.
The data is presented as excel files zipped into one folder.
University of Southampton
Kapur, Omesh
2be52575-505f-472f-ad9c-ce6fe84c20fd
Kapur, Omesh
2be52575-505f-472f-ad9c-ce6fe84c20fd
Kapur, Omesh
(2024)
Dataset in support of the journal article 'An ultra high-endurance memristor using back-end-of-line amorphous SiC'.
University of Southampton
doi:10.5258/SOTON/D3073
[Dataset]
Abstract
Integrating resistive memory or neuromorphic memristors into mainstream silicon technology can be substantially facilitated if the memories are built in the back-end-of-line (BEOL) and stacked directly above the logic circuitries. Here we report a promising memristor employing a plasma-enhanced chemical vapour deposition (PECVD) bilayer of amorphous SiC/Si as device layer and Cu as an active electrode. Its endurance exceeds one billion cycles with an ON/OFF ratio of ca. two orders of magnitude. Resistance drift is observed in the first 200 million cycles, after which the devices settle with a coefficient of variation of ca. 10% for both the low and high resistance states. Ohmic conduction in the low resistance state is attributed to the formation of Cu conductive filaments inside the bilayer structure, where the nanoscale grain boundaries in the Si layer provide the pre-defined pathway for Cu ion migration. Rupture of the conductive filament leads to current conduction dominated by reverse bias Schottky emission. Multistate switching is achieved by precisely controlling the pulse conditions for potential neuromorphic computing applications. The PECVD deposition method employed here has been frequently used to deposit typical BEOL SiOC low-k interlayer dielectrics. This makes this a unique memristor system with great potential for integration.
The data is presented as excel files zipped into one folder.
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Dataset.zip
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Published date: May 2024
Identifiers
Local EPrints ID: 490522
URI: http://eprints.soton.ac.uk/id/eprint/490522
PURE UUID: 39d5858b-fd9c-4b4f-922c-dd039152530f
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Date deposited: 29 May 2024 16:45
Last modified: 30 May 2024 16:40
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Creator:
Omesh Kapur
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