Elucidating the origin of resistive switching in ultrathin hafnium oxides through high spatial resolution tools

Y. Shi; Y. Ji; F. Hui; V. Iglesias; M. Porti; M. Nafria; E. Miranda; G. Bersuker; M. Lanza

doi:10.1149/06414.0019ecst

Elucidating the origin of resistive switching in ultrathin hafnium oxides through high spatial resolution tools

Y. Shi, Y. Ji, F. Hui, V. Iglesias, M. Porti, M. Nafria, E. Miranda, G. Bersuker, M. Lanza

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

7 Scopus citations

Abstract

A new generation of non-volatile memories that store information in a metal/insulator/metal cell with switchable electrical resistance is gaining attention due to its simple structure and high yield. Despite extensive device level measurements have been performed, the origin of the resistive switching remains unclear. In this work, we use a disruptive approach to characterize cyclic resistivity changes at the nanoscale, combining a standard conductive atomic force microscope and a semiconductor parameter analyzer. Using this setup, we are able to assess the origin of resistive switching in Hafnium-based oxides, which takes place at the grain boundaries of polycrystalline stacks, and further calculations corroborate the local nature of this phenomenon.

Original language	English (US)
Title of host publication	ECS Transactions
Publisher	Electrochemical Society Inc.ecs@electrochem.org
Pages	19-28
Number of pages	10
DOIs	https://doi.org/10.1149/06414.0019ecst
State	Published - Jan 1 2014
Externally published	Yes

Bibliographical note

Generated from Scopus record by KAUST IRTS on 2021-03-16

ASJC Scopus subject areas

Engineering(all)

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10.1149/06414.0019ecst

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title = "Elucidating the origin of resistive switching in ultrathin hafnium oxides through high spatial resolution tools",

abstract = "A new generation of non-volatile memories that store information in a metal/insulator/metal cell with switchable electrical resistance is gaining attention due to its simple structure and high yield. Despite extensive device level measurements have been performed, the origin of the resistive switching remains unclear. In this work, we use a disruptive approach to characterize cyclic resistivity changes at the nanoscale, combining a standard conductive atomic force microscope and a semiconductor parameter analyzer. Using this setup, we are able to assess the origin of resistive switching in Hafnium-based oxides, which takes place at the grain boundaries of polycrystalline stacks, and further calculations corroborate the local nature of this phenomenon.",

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AU - Shi, Y.

AU - Ji, Y.

AU - Hui, F.

AU - Iglesias, V.

AU - Porti, M.

AU - Nafria, M.

AU - Miranda, E.

AU - Bersuker, G.

AU - Lanza, M.

N1 - Generated from Scopus record by KAUST IRTS on 2021-03-16

PY - 2014/1/1

Y1 - 2014/1/1

N2 - A new generation of non-volatile memories that store information in a metal/insulator/metal cell with switchable electrical resistance is gaining attention due to its simple structure and high yield. Despite extensive device level measurements have been performed, the origin of the resistive switching remains unclear. In this work, we use a disruptive approach to characterize cyclic resistivity changes at the nanoscale, combining a standard conductive atomic force microscope and a semiconductor parameter analyzer. Using this setup, we are able to assess the origin of resistive switching in Hafnium-based oxides, which takes place at the grain boundaries of polycrystalline stacks, and further calculations corroborate the local nature of this phenomenon.

AB - A new generation of non-volatile memories that store information in a metal/insulator/metal cell with switchable electrical resistance is gaining attention due to its simple structure and high yield. Despite extensive device level measurements have been performed, the origin of the resistive switching remains unclear. In this work, we use a disruptive approach to characterize cyclic resistivity changes at the nanoscale, combining a standard conductive atomic force microscope and a semiconductor parameter analyzer. Using this setup, we are able to assess the origin of resistive switching in Hafnium-based oxides, which takes place at the grain boundaries of polycrystalline stacks, and further calculations corroborate the local nature of this phenomenon.

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DO - 10.1149/06414.0019ecst

M3 - Conference contribution

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PB - Electrochemical Society Inc.ecs@electrochem.org

ER -

Elucidating the origin of resistive switching in ultrathin hafnium oxides through high spatial resolution tools

Abstract

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