Resistive switching memory performance in oxide hetero-nanocrystals with well-controlled interfaces

Takafumi Ishibe; Yoshiki Maeda; Tsukasa Terada; Nobuyasu Naruse; Yutaka Mera; Eiichi Kobayashi; Yoshiaki Nakamura

doi:10.1080/14686996.2020.1736948

Resistive switching memory performance in oxide hetero-nanocrystals with well-controlled interfaces

Takafumi Ishibe, Yoshiki Maeda, Tsukasa Terada, Nobuyasu Naruse, Yutaka Mera, Eiichi Kobayashi, Yoshiaki Nakamura

研究成果: Article › 査読

20 被引用数 (Scopus)

抄録

For realization of new informative systems, the memristor working like synapse has drawn much attention. We developed isolated high-density Fe₃O₄ nanocrystals on Ge nuclei/Si with uniform and high resistive switching performance using low-temperature growth. The Fe₃O₄ nanocrystals on Ge nuclei had a well-controlled interface (Fe₃O₄/GeO_x/Ge) composed of high-crystallinity Fe₃O₄ and high-quality GeO_x layers. The nanocrystals showed uniform resistive switching characteristics (high switching probability of ~90%) and relatively high Off/On resistance ratio (~58). The high-quality interface enables electric field application to Fe₃O₄ and GeO_x near the interface, which leads to effective positively charged oxygen vacancy movement, resulting in high-performance resistive switching. Furthermore, we successfully observed memory effect in nanocrystals with well-controlled interface. The experimental confirmation of the memory effect existence even in ultrasmall nanocrystals is significant for realizing non-volatile nanocrystal memory leading to neuromorphic devices.

本文言語	English
ページ（範囲）	195-204
ページ数	10
ジャーナル	Science and Technology of Advanced Materials
巻	21
号	1
DOI	https://doi.org/10.1080/14686996.2020.1736948
出版ステータス	Published - 2020 1月 31
外部発表	はい

ASJC Scopus subject areas

材料科学（全般）

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10.1080/14686996.2020.1736948

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title = "Resistive switching memory performance in oxide hetero-nanocrystals with well-controlled interfaces",

abstract = "For realization of new informative systems, the memristor working like synapse has drawn much attention. We developed isolated high-density Fe3O4 nanocrystals on Ge nuclei/Si with uniform and high resistive switching performance using low-temperature growth. The Fe3O4 nanocrystals on Ge nuclei had a well-controlled interface (Fe3O4/GeOx/Ge) composed of high-crystallinity Fe3O4 and high-quality GeOx layers. The nanocrystals showed uniform resistive switching characteristics (high switching probability of ~90%) and relatively high Off/On resistance ratio (~58). The high-quality interface enables electric field application to Fe3O4 and GeOx near the interface, which leads to effective positively charged oxygen vacancy movement, resulting in high-performance resistive switching. Furthermore, we successfully observed memory effect in nanocrystals with well-controlled interface. The experimental confirmation of the memory effect existence even in ultrasmall nanocrystals is significant for realizing non-volatile nanocrystal memory leading to neuromorphic devices.",

keywords = "212 Surface and interfaces, Memristor, germanium, interface control, iron oxide, nanocrystal, resistive switching characteristics, silicon",

author = "Takafumi Ishibe and Yoshiki Maeda and Tsukasa Terada and Nobuyasu Naruse and Yutaka Mera and Eiichi Kobayashi and Yoshiaki Nakamura",

note = "Funding Information: This work was supported by a Grant-in-Aid for Scientific Research A Grant No. [16H02078 and 19H00853] and for Exploratory Research [19K22110]; Japan Society for the Promotion of Science. Publisher Copyright: {\textcopyright} 2020, {\textcopyright} 2020 The Author(s). Published by National Institute for Materials Science in partnership with Taylor & Francis Group.",

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AU - Ishibe, Takafumi

AU - Maeda, Yoshiki

AU - Terada, Tsukasa

AU - Naruse, Nobuyasu

AU - Mera, Yutaka

AU - Kobayashi, Eiichi

AU - Nakamura, Yoshiaki

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PY - 2020/1/31

Y1 - 2020/1/31

N2 - For realization of new informative systems, the memristor working like synapse has drawn much attention. We developed isolated high-density Fe3O4 nanocrystals on Ge nuclei/Si with uniform and high resistive switching performance using low-temperature growth. The Fe3O4 nanocrystals on Ge nuclei had a well-controlled interface (Fe3O4/GeOx/Ge) composed of high-crystallinity Fe3O4 and high-quality GeOx layers. The nanocrystals showed uniform resistive switching characteristics (high switching probability of ~90%) and relatively high Off/On resistance ratio (~58). The high-quality interface enables electric field application to Fe3O4 and GeOx near the interface, which leads to effective positively charged oxygen vacancy movement, resulting in high-performance resistive switching. Furthermore, we successfully observed memory effect in nanocrystals with well-controlled interface. The experimental confirmation of the memory effect existence even in ultrasmall nanocrystals is significant for realizing non-volatile nanocrystal memory leading to neuromorphic devices.

AB - For realization of new informative systems, the memristor working like synapse has drawn much attention. We developed isolated high-density Fe3O4 nanocrystals on Ge nuclei/Si with uniform and high resistive switching performance using low-temperature growth. The Fe3O4 nanocrystals on Ge nuclei had a well-controlled interface (Fe3O4/GeOx/Ge) composed of high-crystallinity Fe3O4 and high-quality GeOx layers. The nanocrystals showed uniform resistive switching characteristics (high switching probability of ~90%) and relatively high Off/On resistance ratio (~58). The high-quality interface enables electric field application to Fe3O4 and GeOx near the interface, which leads to effective positively charged oxygen vacancy movement, resulting in high-performance resistive switching. Furthermore, we successfully observed memory effect in nanocrystals with well-controlled interface. The experimental confirmation of the memory effect existence even in ultrasmall nanocrystals is significant for realizing non-volatile nanocrystal memory leading to neuromorphic devices.

KW - 212 Surface and interfaces

KW - Memristor

KW - germanium

KW - interface control

KW - iron oxide

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KW - resistive switching characteristics

KW - silicon

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Resistive switching memory performance in oxide hetero-nanocrystals with well-controlled interfaces

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