The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory

The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory

Abstract Resistive random access memory (RRAM) has emerged as a new discipline promoting the development of new materials and devices toward a broad range of electronic and energy applications. Here, we realized a memristive device with weak dependence on the top electrodes and demonstrated the quan...

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Main Authors: Mengting Zhao, Xiaobing Yan, Long Ren, Mengliu Zhao, Fei Guo, Jincheng Zhuang, Yi Du, Weichang Hao
Format: Article
Language:English
Published: Wiley 2020-09-01
Series:InfoMat
Subjects:
Bi nanowires
BiVO4
quantum conductance
RRAM
Online Access:https://doi.org/10.1002/inf2.12085
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spelling doaj-f22b5b3f3bf44aafab5e1bf66f5469ae2020-11-25T03:06:48ZengWileyInfoMat2567-31652020-09-012596096710.1002/inf2.12085The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memoryMengting Zhao0Xiaobing Yan1Long Ren2Mengliu Zhao3Fei Guo4Jincheng Zhuang5Yi Du6Weichang Hao7School of Physics and BUAA‐UOW Joint Research Centre Beihang University Beijing ChinaCollege of Electronic and Information Engineering Hebei University Baoding ChinaInstitute for Superconducting and Electronic Materials University of Wollongong Wollongong New South Wales AustraliaCollege of Electronic and Information Engineering Hebei University Baoding ChinaSchool of Physics and BUAA‐UOW Joint Research Centre Beihang University Beijing ChinaSchool of Physics and BUAA‐UOW Joint Research Centre Beihang University Beijing ChinaSchool of Physics and BUAA‐UOW Joint Research Centre Beihang University Beijing ChinaSchool of Physics and BUAA‐UOW Joint Research Centre Beihang University Beijing ChinaAbstract Resistive random access memory (RRAM) has emerged as a new discipline promoting the development of new materials and devices toward a broad range of electronic and energy applications. Here, we realized a memristive device with weak dependence on the top electrodes and demonstrated the quantized conductance (QC) nature in BiVO4 matrix. The electronic properties have been investigated by the measurements of I‐V curves, where the resistive switching (RS) phenomenon with stable switching ratio and excellent long‐term retention capabilities are identified. Two more inert materials, TiN and Pd, are applied as the top electrodes to exclude the influence of electrodes on the RS states and QC behavior. The X‐ray photoelectron spectroscopy results and transport measurements reveal that the conductive filament (CF) is composed by elemental bismuth. The naturally existed oxygen vacancies in BiVO4 matrix plays as the role of catalyst in the formation and dissolution of CF in BiVO4‐based RRAM device, which is the primary cause for the observed weak dependence of switching performance in this device on the type of top electrodes. Our results clearly illustrate that BiVO4 could be a new idea platform to realize the high scalability, high cycling endurance, and multilevel storage RRAM devices.https://doi.org/10.1002/inf2.12085Bi nanowiresBiVO4quantum conductanceRRAM
collection DOAJ
language English
format Article
sources DOAJ
author Mengting Zhao
Xiaobing Yan
Long Ren
Mengliu Zhao
Fei Guo
Jincheng Zhuang
Yi Du
Weichang Hao
spellingShingle Mengting Zhao
Xiaobing Yan
Long Ren
Mengliu Zhao
Fei Guo
Jincheng Zhuang
Yi Du
Weichang Hao
The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
InfoMat
Bi nanowires
BiVO4
quantum conductance
RRAM
author_facet Mengting Zhao
Xiaobing Yan
Long Ren
Mengliu Zhao
Fei Guo
Jincheng Zhuang
Yi Du
Weichang Hao
author_sort Mengting Zhao
title The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
title_short The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
title_full The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
title_fullStr The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
title_full_unstemmed The role of oxygen vacancies in the high cycling endurance and quantum conductance in BiVO4‐based resistive switching memory
title_sort role of oxygen vacancies in the high cycling endurance and quantum conductance in bivo4‐based resistive switching memory
publisher Wiley
series InfoMat
issn 2567-3165
publishDate 2020-09-01
description Abstract Resistive random access memory (RRAM) has emerged as a new discipline promoting the development of new materials and devices toward a broad range of electronic and energy applications. Here, we realized a memristive device with weak dependence on the top electrodes and demonstrated the quantized conductance (QC) nature in BiVO4 matrix. The electronic properties have been investigated by the measurements of I‐V curves, where the resistive switching (RS) phenomenon with stable switching ratio and excellent long‐term retention capabilities are identified. Two more inert materials, TiN and Pd, are applied as the top electrodes to exclude the influence of electrodes on the RS states and QC behavior. The X‐ray photoelectron spectroscopy results and transport measurements reveal that the conductive filament (CF) is composed by elemental bismuth. The naturally existed oxygen vacancies in BiVO4 matrix plays as the role of catalyst in the formation and dissolution of CF in BiVO4‐based RRAM device, which is the primary cause for the observed weak dependence of switching performance in this device on the type of top electrodes. Our results clearly illustrate that BiVO4 could be a new idea platform to realize the high scalability, high cycling endurance, and multilevel storage RRAM devices.
topic Bi nanowires
BiVO4
quantum conductance
RRAM
url https://doi.org/10.1002/inf2.12085
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