Dynamic evolution of conducting nanofilament in resistive switching memories

Jui Yuan Chen; Cheng Lun Hsin; Chun Wei Huang; Chung Hua Chiu; Yu Ting Huang; Su Jien Lin; Wen Wei Wu; Lih Juann Chen

doi:10.1021/nl4015638

Dynamic evolution of conducting nanofilament in resistive switching memories

Jui Yuan Chen, Cheng Lun Hsin, Chun Wei Huang, Chung Hua Chiu, Yu Ting Huang, Su Jien Lin, Wen Wei Wu, Lih Juann Chen

電機工程學系

研究成果: 雜誌貢獻 › 期刊論文 › 同行評審

342 引文斯高帕斯（Scopus）

摘要

Resistive random access memory (ReRAM) has been considered the most promising next-generation nonvolatile memory. In recent years, the switching behavior has been widely reported, and understanding the switching mechanism can improve the stability and scalability of devices. We designed an innovative sample structure for in situ transmission electron microscopy (TEM) to observe the formation of conductive filaments in the Pt/ZnO/Pt structure in real time. The corresponding current-voltage measurements help us to understand the switching mechanism of ZnO film. In addition, high-resolution transmission electron microscopy (HRTEM) and electron energy loss spectroscopy (EELS) have been used to identify the atomic structure and components of the filament/disrupted region, determining that the conducting paths are caused by the conglomeration of zinc atoms. The behavior of resistive switching is due to the migration of oxygen ions, leading to transformation between Zn-dominated ZnO_1-x and ZnO.

原文	???core.languages.en_GB???
頁（從 - 到）	3671-3677
頁數	7
期刊	Nano Letters
卷	13
發行號	8
DOIs	https://doi.org/10.1021/nl4015638
出版狀態	已出版 - 14 8月 2013

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10.1021/nl4015638

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title = "Dynamic evolution of conducting nanofilament in resistive switching memories",

abstract = "Resistive random access memory (ReRAM) has been considered the most promising next-generation nonvolatile memory. In recent years, the switching behavior has been widely reported, and understanding the switching mechanism can improve the stability and scalability of devices. We designed an innovative sample structure for in situ transmission electron microscopy (TEM) to observe the formation of conductive filaments in the Pt/ZnO/Pt structure in real time. The corresponding current-voltage measurements help us to understand the switching mechanism of ZnO film. In addition, high-resolution transmission electron microscopy (HRTEM) and electron energy loss spectroscopy (EELS) have been used to identify the atomic structure and components of the filament/disrupted region, determining that the conducting paths are caused by the conglomeration of zinc atoms. The behavior of resistive switching is due to the migration of oxygen ions, leading to transformation between Zn-dominated ZnO1-x and ZnO.",

keywords = "In situ TEM, nanofilament, redox, resistive switching, RRAM, unipolar",

author = "Chen, {Jui Yuan} and Hsin, {Cheng Lun} and Huang, {Chun Wei} and Chiu, {Chung Hua} and Huang, {Yu Ting} and Lin, {Su Jien} and Wu, {Wen Wei} and Chen, {Lih Juann}",

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AU - Chen, Jui Yuan

AU - Hsin, Cheng Lun

AU - Huang, Chun Wei

AU - Chiu, Chung Hua

AU - Huang, Yu Ting

AU - Lin, Su Jien

AU - Wu, Wen Wei

AU - Chen, Lih Juann

PY - 2013/8/14

Y1 - 2013/8/14

N2 - Resistive random access memory (ReRAM) has been considered the most promising next-generation nonvolatile memory. In recent years, the switching behavior has been widely reported, and understanding the switching mechanism can improve the stability and scalability of devices. We designed an innovative sample structure for in situ transmission electron microscopy (TEM) to observe the formation of conductive filaments in the Pt/ZnO/Pt structure in real time. The corresponding current-voltage measurements help us to understand the switching mechanism of ZnO film. In addition, high-resolution transmission electron microscopy (HRTEM) and electron energy loss spectroscopy (EELS) have been used to identify the atomic structure and components of the filament/disrupted region, determining that the conducting paths are caused by the conglomeration of zinc atoms. The behavior of resistive switching is due to the migration of oxygen ions, leading to transformation between Zn-dominated ZnO1-x and ZnO.

AB - Resistive random access memory (ReRAM) has been considered the most promising next-generation nonvolatile memory. In recent years, the switching behavior has been widely reported, and understanding the switching mechanism can improve the stability and scalability of devices. We designed an innovative sample structure for in situ transmission electron microscopy (TEM) to observe the formation of conductive filaments in the Pt/ZnO/Pt structure in real time. The corresponding current-voltage measurements help us to understand the switching mechanism of ZnO film. In addition, high-resolution transmission electron microscopy (HRTEM) and electron energy loss spectroscopy (EELS) have been used to identify the atomic structure and components of the filament/disrupted region, determining that the conducting paths are caused by the conglomeration of zinc atoms. The behavior of resistive switching is due to the migration of oxygen ions, leading to transformation between Zn-dominated ZnO1-x and ZnO.

KW - In situ TEM

KW - nanofilament

KW - redox

KW - resistive switching

KW - RRAM

KW - unipolar

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JO - Nano Letters

JF - Nano Letters

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Dynamic evolution of conducting nanofilament in resistive switching memories

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