Photoenhanced Electroresistance at Dislocation-Mediated Phase Boundary

Jing Wang; Ruixue Zhu; Ji Ma; Huayu Yang; Yuanyuan Fan; Mingfeng Chen; Yuanwei Sun; Peng Gao; Houbing Huang; Jinxing Zhang; Jing Ma; Ce Wen Nan

doi:10.1021/acsami.1c25259

Photoenhanced Electroresistance at Dislocation-Mediated Phase Boundary

Jing Wang^*, Ruixue Zhu, Ji Ma, Huayu Yang, Yuanyuan Fan, Mingfeng Chen, Yuanwei Sun, Peng Gao, Houbing Huang, Jinxing Zhang, Jing Ma^*, Ce Wen Nan

^*Corresponding author for this work

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

5 Citations (Scopus)

Abstract

Ferroelectric tunneling junctions have attracted intensive research interest due to their potential applications in high-density data storage and neural network computing. However, the prerequisite of an ultrathin ferroelectric tunneling barrier makes it a great challenge to simultaneously implement the robust polarization and negligible leakage current in a ferroelectric thin film, both of which are significant for ferroelectric tunneling junctions with reliable operating performance. Here, we observe a large tunneling electroresistance effect of ∼1.0 × 10⁴% across the BiFeO₃nanoisland edge, where the intrinsic ferroelectric polarization of the nanoisland makes a major contribution to tuning the barrier height. This phenomenon is beneficial from the artificially designed tunneling barrier between the nanoscale top electrode and the inclined conducting phase boundary, which is located between the rhombohedral-island and tetragonal-film matrix and arranged with the dislocation array. More significantly, the tunneling electroresistance effect is further improved to ∼1.6 × 10⁴% by the introduction of photoinduced carriers, which are separated by the flexoelectric field arising from the dislocations.

Original language	English
Pages (from-to)	18662-18670
Number of pages	9
Journal	ACS Applied Materials and Interfaces
Volume	14
Issue number	16
DOIs	https://doi.org/10.1021/acsami.1c25259
Publication status	Published - 27 Apr 2022

Keywords

BiFeOnanoislands
dislocations
ferroelectric tunneling junction
flexoelectric effect
tunneling electroresistance effect

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10.1021/acsami.1c25259

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title = "Photoenhanced Electroresistance at Dislocation-Mediated Phase Boundary",

abstract = "Ferroelectric tunneling junctions have attracted intensive research interest due to their potential applications in high-density data storage and neural network computing. However, the prerequisite of an ultrathin ferroelectric tunneling barrier makes it a great challenge to simultaneously implement the robust polarization and negligible leakage current in a ferroelectric thin film, both of which are significant for ferroelectric tunneling junctions with reliable operating performance. Here, we observe a large tunneling electroresistance effect of ∼1.0 × 104% across the BiFeO3nanoisland edge, where the intrinsic ferroelectric polarization of the nanoisland makes a major contribution to tuning the barrier height. This phenomenon is beneficial from the artificially designed tunneling barrier between the nanoscale top electrode and the inclined conducting phase boundary, which is located between the rhombohedral-island and tetragonal-film matrix and arranged with the dislocation array. More significantly, the tunneling electroresistance effect is further improved to ∼1.6 × 104% by the introduction of photoinduced carriers, which are separated by the flexoelectric field arising from the dislocations.",

keywords = "BiFeOnanoislands, dislocations, ferroelectric tunneling junction, flexoelectric effect, tunneling electroresistance effect",

author = "Jing Wang and Ruixue Zhu and Ji Ma and Huayu Yang and Yuanyuan Fan and Mingfeng Chen and Yuanwei Sun and Peng Gao and Houbing Huang and Jinxing Zhang and Jing Ma and Nan, {Ce Wen}",

year = "2022",

month = apr,

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doi = "10.1021/acsami.1c25259",

language = "English",

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journal = "ACS Applied Materials and Interfaces",

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TY - JOUR

T1 - Photoenhanced Electroresistance at Dislocation-Mediated Phase Boundary

AU - Wang, Jing

AU - Zhu, Ruixue

AU - Ma, Ji

AU - Yang, Huayu

AU - Fan, Yuanyuan

AU - Chen, Mingfeng

AU - Sun, Yuanwei

AU - Gao, Peng

AU - Huang, Houbing

AU - Zhang, Jinxing

AU - Ma, Jing

AU - Nan, Ce Wen

PY - 2022/4/27

Y1 - 2022/4/27

N2 - Ferroelectric tunneling junctions have attracted intensive research interest due to their potential applications in high-density data storage and neural network computing. However, the prerequisite of an ultrathin ferroelectric tunneling barrier makes it a great challenge to simultaneously implement the robust polarization and negligible leakage current in a ferroelectric thin film, both of which are significant for ferroelectric tunneling junctions with reliable operating performance. Here, we observe a large tunneling electroresistance effect of ∼1.0 × 104% across the BiFeO3nanoisland edge, where the intrinsic ferroelectric polarization of the nanoisland makes a major contribution to tuning the barrier height. This phenomenon is beneficial from the artificially designed tunneling barrier between the nanoscale top electrode and the inclined conducting phase boundary, which is located between the rhombohedral-island and tetragonal-film matrix and arranged with the dislocation array. More significantly, the tunneling electroresistance effect is further improved to ∼1.6 × 104% by the introduction of photoinduced carriers, which are separated by the flexoelectric field arising from the dislocations.

AB - Ferroelectric tunneling junctions have attracted intensive research interest due to their potential applications in high-density data storage and neural network computing. However, the prerequisite of an ultrathin ferroelectric tunneling barrier makes it a great challenge to simultaneously implement the robust polarization and negligible leakage current in a ferroelectric thin film, both of which are significant for ferroelectric tunneling junctions with reliable operating performance. Here, we observe a large tunneling electroresistance effect of ∼1.0 × 104% across the BiFeO3nanoisland edge, where the intrinsic ferroelectric polarization of the nanoisland makes a major contribution to tuning the barrier height. This phenomenon is beneficial from the artificially designed tunneling barrier between the nanoscale top electrode and the inclined conducting phase boundary, which is located between the rhombohedral-island and tetragonal-film matrix and arranged with the dislocation array. More significantly, the tunneling electroresistance effect is further improved to ∼1.6 × 104% by the introduction of photoinduced carriers, which are separated by the flexoelectric field arising from the dislocations.

KW - BiFeOnanoislands

KW - dislocations

KW - ferroelectric tunneling junction

KW - flexoelectric effect

KW - tunneling electroresistance effect

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U2 - 10.1021/acsami.1c25259

DO - 10.1021/acsami.1c25259

M3 - Article

C2 - 35430815

AN - SCOPUS:85128620509

SN - 1944-8244

VL - 14

SP - 18662

EP - 18670

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 16

ER -

Photoenhanced Electroresistance at Dislocation-Mediated Phase Boundary

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Keywords

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