Self-directed channel memristor for high temperature operation

Kristy A. Campbell

doi:10.1016/j.mejo.2016.11.006

Self-directed channel memristor for high temperature operation

Kristy A. Campbell

Electrical Engineering Department

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

108 Scopus citations

Abstract

Ion-conducting memristors comprised of the layered chalcogenide materials Ge₂Se₃/SnSe/Ag are described. The memristor, termed a self-directed channel (SDC) device, can be classified as a generic memristor and can tolerate continuous high temperature operation (at least 150 °C). Unlike other chalcogenide-based ion conducting device types, the SDC device does not require complicated fabrication steps, such as photodoping or thermal annealing, making these devices faster and more reliable to fabricate. Device pulsed response shows fast state switching in the 10⁻⁹ s range. Device cycling at both room temperature and 140 °C show write endurance of at least 1 billion.

Original language	English
Pages (from-to)	10-14
Number of pages	5
Journal	Microelectronics Journal
Volume	59
DOIs	https://doi.org/10.1016/j.mejo.2016.11.006
State	Published - 1 Jan 2017

Keywords

Chalcogenide
Ion-conductor
Memristor
Neuromorphic
Non-volatile memory
RRAM

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10.1016/j.mejo.2016.11.006

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title = "Self-directed channel memristor for high temperature operation",

abstract = "Ion-conducting memristors comprised of the layered chalcogenide materials Ge2Se3/SnSe/Ag are described. The memristor, termed a self-directed channel (SDC) device, can be classified as a generic memristor and can tolerate continuous high temperature operation (at least 150 °C). Unlike other chalcogenide-based ion conducting device types, the SDC device does not require complicated fabrication steps, such as photodoping or thermal annealing, making these devices faster and more reliable to fabricate. Device pulsed response shows fast state switching in the 10−9 s range. Device cycling at both room temperature and 140 °C show write endurance of at least 1 billion.",

keywords = "Chalcogenide, Ion-conductor, Memristor, Neuromorphic, Non-volatile memory, RRAM",

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N2 - Ion-conducting memristors comprised of the layered chalcogenide materials Ge2Se3/SnSe/Ag are described. The memristor, termed a self-directed channel (SDC) device, can be classified as a generic memristor and can tolerate continuous high temperature operation (at least 150 °C). Unlike other chalcogenide-based ion conducting device types, the SDC device does not require complicated fabrication steps, such as photodoping or thermal annealing, making these devices faster and more reliable to fabricate. Device pulsed response shows fast state switching in the 10−9 s range. Device cycling at both room temperature and 140 °C show write endurance of at least 1 billion.

AB - Ion-conducting memristors comprised of the layered chalcogenide materials Ge2Se3/SnSe/Ag are described. The memristor, termed a self-directed channel (SDC) device, can be classified as a generic memristor and can tolerate continuous high temperature operation (at least 150 °C). Unlike other chalcogenide-based ion conducting device types, the SDC device does not require complicated fabrication steps, such as photodoping or thermal annealing, making these devices faster and more reliable to fabricate. Device pulsed response shows fast state switching in the 10−9 s range. Device cycling at both room temperature and 140 °C show write endurance of at least 1 billion.

KW - Chalcogenide

KW - Ion-conductor

KW - Memristor

KW - Neuromorphic

KW - Non-volatile memory

KW - RRAM

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VL - 59

SP - 10

EP - 14

JO - Microelectronics Journal

JF - Microelectronics Journal

ER -

Self-directed channel memristor for high temperature operation

Abstract

Keywords

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