Spatially-resolved mapping of history-dependent coupled electrochemical and electronical behaviors of electroresistive NiO

Issei Sugiyama; Yunseok Kim; Stephen Jesse; Evgheni Strelcov; Amit Kumar; Alexander Tselev; Ehasan Kabiri Rahani; Vivek B. Shenoy; Takahisa Yamamoto; Naoya Shibata; Yuichi Ikuhara; Sergei V. Kalinin

doi:10.1038/srep06725

Spatially-resolved mapping of history-dependent coupled electrochemical and electronical behaviors of electroresistive NiO

Issei Sugiyama, Yunseok Kim, Stephen Jesse, Evgheni Strelcov, Amit Kumar, Alexander Tselev, Ehasan Kabiri Rahani, Vivek B. Shenoy, Takahisa Yamamoto, Naoya Shibata, Yuichi Ikuhara, Sergei V. Kalinin

Center for Nanophase Matls Sciences

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

11 Scopus citations

Abstract

Bias-induced oxygen ion dynamics underpins a broad spectrum of electroresistive and memristive phenomena in oxide materials. Although widely studied by device-level and local voltage-current spectroscopies, the relationship between electroresistive phenomena, local electrochemical behaviors, and microstructures remains elusive. Here, the interplay between history-dependent electronic transport and electrochemical phenomena in a NiO single crystalline thin film with a number of well-defined defect types is explored on the nanometer scale using an atomic force microscopy-based technique. A variety of electrochemically-active regions were observed and spatially resolved relationship between the electronic and electrochemical phenomena was revealed. The regions with pronounced electroresistive activity were further correlated with defects identified by scanning transmission electron microscopy. Using fully coupled mechanical-electrochemical modeling, we illustrate that the spatial distribution of strain plays an important role in electrochemical and electroresistive phenomena. These studies illustrate an approach for simultaneous mapping of the electronic and ionic transport on a single defective structure level such as dislocations or interfaces, and pave the way for creating libraries of defect-specific electrochemical responses.

Original language	English
Article number	6725
Journal	Scientific Reports
Volume	4
DOIs	https://doi.org/10.1038/srep06725
State	Published - Oct 22 2014

Funding

This study was supported in part by the Grant-in-Aid for Scientific Research on Innovative Areas "Nano Informatics" (grant number 25106003) from JSPS. I.S. was supported as JSPS research fellow. N.S. acknowledges support from JST-PRESTO and JSPS KAKENHI Grant number 2368093. The AFM portion of this research was conducted at the Center for Nanophase Materials Sciences (Y.K., S.V.K., E.S., S.J.), which is sponsored at Oak Ridge National Laboratory by the Scientific User Facilities Division, Office of Basic Energy Sciences, U.S. Department of Energy under proposal number CNMS2012-230. STEM/ EELS was carried out in the research Hub for Advanced Nano Characterization, the University of Tokyo, under the support of "Nanotechnology Platform" (project No.12024046) by MEXT.

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title = "Spatially-resolved mapping of history-dependent coupled electrochemical and electronical behaviors of electroresistive NiO",

abstract = "Bias-induced oxygen ion dynamics underpins a broad spectrum of electroresistive and memristive phenomena in oxide materials. Although widely studied by device-level and local voltage-current spectroscopies, the relationship between electroresistive phenomena, local electrochemical behaviors, and microstructures remains elusive. Here, the interplay between history-dependent electronic transport and electrochemical phenomena in a NiO single crystalline thin film with a number of well-defined defect types is explored on the nanometer scale using an atomic force microscopy-based technique. A variety of electrochemically-active regions were observed and spatially resolved relationship between the electronic and electrochemical phenomena was revealed. The regions with pronounced electroresistive activity were further correlated with defects identified by scanning transmission electron microscopy. Using fully coupled mechanical-electrochemical modeling, we illustrate that the spatial distribution of strain plays an important role in electrochemical and electroresistive phenomena. These studies illustrate an approach for simultaneous mapping of the electronic and ionic transport on a single defective structure level such as dislocations or interfaces, and pave the way for creating libraries of defect-specific electrochemical responses.",

author = "Issei Sugiyama and Yunseok Kim and Stephen Jesse and Evgheni Strelcov and Amit Kumar and Alexander Tselev and Rahani, {Ehasan Kabiri} and Shenoy, {Vivek B.} and Takahisa Yamamoto and Naoya Shibata and Yuichi Ikuhara and Kalinin, {Sergei V.}",

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AU - Sugiyama, Issei

AU - Kim, Yunseok

AU - Jesse, Stephen

AU - Strelcov, Evgheni

AU - Kumar, Amit

AU - Tselev, Alexander

AU - Rahani, Ehasan Kabiri

AU - Shenoy, Vivek B.

AU - Yamamoto, Takahisa

AU - Shibata, Naoya

AU - Ikuhara, Yuichi

AU - Kalinin, Sergei V.

PY - 2014/10/22

Y1 - 2014/10/22

N2 - Bias-induced oxygen ion dynamics underpins a broad spectrum of electroresistive and memristive phenomena in oxide materials. Although widely studied by device-level and local voltage-current spectroscopies, the relationship between electroresistive phenomena, local electrochemical behaviors, and microstructures remains elusive. Here, the interplay between history-dependent electronic transport and electrochemical phenomena in a NiO single crystalline thin film with a number of well-defined defect types is explored on the nanometer scale using an atomic force microscopy-based technique. A variety of electrochemically-active regions were observed and spatially resolved relationship between the electronic and electrochemical phenomena was revealed. The regions with pronounced electroresistive activity were further correlated with defects identified by scanning transmission electron microscopy. Using fully coupled mechanical-electrochemical modeling, we illustrate that the spatial distribution of strain plays an important role in electrochemical and electroresistive phenomena. These studies illustrate an approach for simultaneous mapping of the electronic and ionic transport on a single defective structure level such as dislocations or interfaces, and pave the way for creating libraries of defect-specific electrochemical responses.

AB - Bias-induced oxygen ion dynamics underpins a broad spectrum of electroresistive and memristive phenomena in oxide materials. Although widely studied by device-level and local voltage-current spectroscopies, the relationship between electroresistive phenomena, local electrochemical behaviors, and microstructures remains elusive. Here, the interplay between history-dependent electronic transport and electrochemical phenomena in a NiO single crystalline thin film with a number of well-defined defect types is explored on the nanometer scale using an atomic force microscopy-based technique. A variety of electrochemically-active regions were observed and spatially resolved relationship between the electronic and electrochemical phenomena was revealed. The regions with pronounced electroresistive activity were further correlated with defects identified by scanning transmission electron microscopy. Using fully coupled mechanical-electrochemical modeling, we illustrate that the spatial distribution of strain plays an important role in electrochemical and electroresistive phenomena. These studies illustrate an approach for simultaneous mapping of the electronic and ionic transport on a single defective structure level such as dislocations or interfaces, and pave the way for creating libraries of defect-specific electrochemical responses.

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JO - Scientific Reports

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Spatially-resolved mapping of history-dependent coupled electrochemical and electronical behaviors of electroresistive NiO

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