Homo-layer hafnia-based memristor with large analog switching window

The fast development of high-accuracy neuromorphic computing requires stable analog memristors. While filamentary memory switching is very common in binary oxides, their resistive switching usually involves abrupt changes due to the rupture or reformation of metallic filaments. In this work, we desi...

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Veröffentlicht in:	Applied physics letters 2021-01, Vol.118 (4)
Hauptverfasser:	Bai, Na, Tian, Baoyi, Mao, Ge-Qi, Xue, Kan-Hao, Wang, Tao, Yuan, Jun-Hui, Liu, Xiaoxin, Li, Zhaonan, Guo, Shen, Zhou, Zuopai, Liu, Nian, Lu, Hong, Tang, Xiaodong, Sun, Huajun, Miao, Xiangshui
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Sprache:	eng
Schlagworte:	Applied physics Computation Electroforming Filaments First principles Hafnium oxide Linearity Memristors Oxygen Switching Vacancies
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creator	Bai, Na Tian, Baoyi Mao, Ge-Qi Xue, Kan-Hao Wang, Tao Yuan, Jun-Hui Liu, Xiaoxin Li, Zhaonan Guo, Shen Zhou, Zuopai Liu, Nian Lu, Hong Tang, Xiaodong Sun, Huajun Miao, Xiangshui
description	The fast development of high-accuracy neuromorphic computing requires stable analog memristors. While filamentary memory switching is very common in binary oxides, their resistive switching usually involves abrupt changes due to the rupture or reformation of metallic filaments. In this work, we designed a memristor consisting of dual-layer HfOy/HfOx, with different concentrations of oxygen vacancies (y > x). During the electroforming process, both the migration of existing oxygen vacancies in HfOx and the generation of new oxygen vacancies in HfOy occur simultaneously, leaving a semiconducting part close to the HfOy/HfOx interface. The resulting filament is not metallic as a whole, as revealed by first principles calculations. Such a device demonstrates excellent switching uniformity as well as highly gradual resistance change, ideal for neuromorphic computing. Through fine tuning of the filament structure, the device achieves low variation, high speed, gradual SET and RESET processes, and hundreds of stable multi-level state behaviors. The long-term synaptic plasticity was further achieved, showing good linearity and large analog switching window (ΔG as high as 487.5 μS). This works affords a route toward a gradual resistance change in oxide-based memristors.
doi_str_mv	10.1063/5.0032556
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While filamentary memory switching is very common in binary oxides, their resistive switching usually involves abrupt changes due to the rupture or reformation of metallic filaments. In this work, we designed a memristor consisting of dual-layer HfOy/HfOx, with different concentrations of oxygen vacancies (y > x). During the electroforming process, both the migration of existing oxygen vacancies in HfOx and the generation of new oxygen vacancies in HfOy occur simultaneously, leaving a semiconducting part close to the HfOy/HfOx interface. The resulting filament is not metallic as a whole, as revealed by first principles calculations. Such a device demonstrates excellent switching uniformity as well as highly gradual resistance change, ideal for neuromorphic computing. Through fine tuning of the filament structure, the device achieves low variation, high speed, gradual SET and RESET processes, and hundreds of stable multi-level state behaviors. The long-term synaptic plasticity was further achieved, showing good linearity and large analog switching window (ΔG as high as 487.5 μS). This works affords a route toward a gradual resistance change in oxide-based memristors.</description><identifier>ISSN: 0003-6951</identifier><identifier>EISSN: 1077-3118</identifier><identifier>DOI: 10.1063/5.0032556</identifier><identifier>CODEN: APPLAB</identifier><language>eng</language><publisher>Melville: American Institute of Physics</publisher><subject>Applied physics ; Computation ; Electroforming ; Filaments ; First principles ; Hafnium oxide ; Linearity ; Memristors ; Oxygen ; Switching ; Vacancies</subject><ispartof>Applied physics letters, 2021-01, Vol.118 (4)</ispartof><rights>Author(s)</rights><rights>2021 Author(s). 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While filamentary memory switching is very common in binary oxides, their resistive switching usually involves abrupt changes due to the rupture or reformation of metallic filaments. In this work, we designed a memristor consisting of dual-layer HfOy/HfOx, with different concentrations of oxygen vacancies (y > x). During the electroforming process, both the migration of existing oxygen vacancies in HfOx and the generation of new oxygen vacancies in HfOy occur simultaneously, leaving a semiconducting part close to the HfOy/HfOx interface. The resulting filament is not metallic as a whole, as revealed by first principles calculations. Such a device demonstrates excellent switching uniformity as well as highly gradual resistance change, ideal for neuromorphic computing. Through fine tuning of the filament structure, the device achieves low variation, high speed, gradual SET and RESET processes, and hundreds of stable multi-level state behaviors. The long-term synaptic plasticity was further achieved, showing good linearity and large analog switching window (ΔG as high as 487.5 μS). 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subjects	Applied physics Computation Electroforming Filaments First principles Hafnium oxide Linearity Memristors Oxygen Switching Vacancies
title	Homo-layer hafnia-based memristor with large analog switching window
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