Interface Engineering of Domain Structures in BiFeO3 Thin Films

Deyang Chen; Zuhuang Chen; Qian He; James D. Clarkson; Claudy R. Serrao; Ajay K. Yadav; Mark E. Nowakowski; Zhen Fan; Long You; Xingsen Gao; Dechang Zeng; Lang Chen; Albina Y. Borisevich; Sayeef Salahuddin; Jun Ming Liu; Jeffrey Bokor

doi:10.1021/acs.nanolett.6b04512

Interface Engineering of Domain Structures in BiFeO₃ Thin Films

Deyang Chen^*
, Zuhuang Chen
, Qian He
, James D. Clarkson
, Claudy R. Serrao
, Ajay K. Yadav
, Mark E. Nowakowski
, Zhen Fan
, Long You
, Xingsen Gao
, Dechang Zeng
, Lang Chen
, Albina Y. Borisevich
, Sayeef Salahuddin
, Jun Ming Liu
, Jeffrey Bokor

^*Corresponding author for this work

South China Normal University
University of California at Berkeley
South China University of Technology
Oak Ridge National Laboratory
Huazhong University of Science and Technology
Southern University of Science and Technology
Nanjing University

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

89 Scopus citations

Abstract

A wealth of fascinating phenomena have been discovered at the BiFeO₃ domain walls, examples such as domain wall conductivity, photovoltaic effects, and magnetoelectric coupling. Thus, the ability to precisely control the domain structures and accurately study their switching behaviors is critical to realize the next generation of novel devices based on domain wall functionalities. In this work, the introduction of a dielectric layer leads to the tunability of the depolarization field both in the multilayers and superlattices, which provides a novel approach to control the domain patterns of BiFeO₃ films. Moreover, we are able to study the switching behavior of the first time obtained periodic 109° stripe domains with a thick bottom electrode. Besides, the precise controlling of pure 71° and 109° periodic stripe domain walls enable us to make a clear demonstration that the exchange bias in the ferromagnet/BiFeO₃ system originates from 109° domain walls. Our findings provide future directions to study the room temperature electric field control of exchange bias and open a new pathway to explore the room temperature multiferroic vortices in the BiFeO₃ system.

Original language	English
Pages (from-to)	486-493
Number of pages	8
Journal	Nano Letters
Volume	17
Issue number	1
DOIs	https://doi.org/10.1021/acs.nanolett.6b04512
State	Published - 11 Jan 2017
Externally published	Yes

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

BiFeO
depolarization field
domain wall
exchange bias
multiferroic
superlattices

Access to Document

10.1021/acs.nanolett.6b04512

Cite this

@article{cfb54f8885234cf79d52b6e6d4656124,

title = "Interface Engineering of Domain Structures in BiFeO3 Thin Films",

abstract = "A wealth of fascinating phenomena have been discovered at the BiFeO3 domain walls, examples such as domain wall conductivity, photovoltaic effects, and magnetoelectric coupling. Thus, the ability to precisely control the domain structures and accurately study their switching behaviors is critical to realize the next generation of novel devices based on domain wall functionalities. In this work, the introduction of a dielectric layer leads to the tunability of the depolarization field both in the multilayers and superlattices, which provides a novel approach to control the domain patterns of BiFeO3 films. Moreover, we are able to study the switching behavior of the first time obtained periodic 109° stripe domains with a thick bottom electrode. Besides, the precise controlling of pure 71° and 109° periodic stripe domain walls enable us to make a clear demonstration that the exchange bias in the ferromagnet/BiFeO3 system originates from 109° domain walls. Our findings provide future directions to study the room temperature electric field control of exchange bias and open a new pathway to explore the room temperature multiferroic vortices in the BiFeO3 system.",

keywords = "BiFeO, depolarization field, domain wall, exchange bias, multiferroic, superlattices",

author = "Deyang Chen and Zuhuang Chen and Qian He and Clarkson, \{James D.\} and Serrao, \{Claudy R.\} and Yadav, \{Ajay K.\} and Nowakowski, \{Mark E.\} and Zhen Fan and Long You and Xingsen Gao and Dechang Zeng and Lang Chen and Borisevich, \{Albina Y.\} and Sayeef Salahuddin and Liu, \{Jun Ming\} and Jeffrey Bokor",

note = "Publisher Copyright: {\textcopyright} 2016 American Chemical Society.",

year = "2017",

month = jan,

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doi = "10.1021/acs.nanolett.6b04512",

language = "英语",

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TY - JOUR

T1 - Interface Engineering of Domain Structures in BiFeO3 Thin Films

AU - Chen, Deyang

AU - Chen, Zuhuang

AU - He, Qian

AU - Clarkson, James D.

AU - Serrao, Claudy R.

AU - Yadav, Ajay K.

AU - Nowakowski, Mark E.

AU - Fan, Zhen

AU - You, Long

AU - Gao, Xingsen

AU - Zeng, Dechang

AU - Chen, Lang

AU - Borisevich, Albina Y.

AU - Salahuddin, Sayeef

AU - Liu, Jun Ming

AU - Bokor, Jeffrey

PY - 2017/1/11

Y1 - 2017/1/11

N2 - A wealth of fascinating phenomena have been discovered at the BiFeO3 domain walls, examples such as domain wall conductivity, photovoltaic effects, and magnetoelectric coupling. Thus, the ability to precisely control the domain structures and accurately study their switching behaviors is critical to realize the next generation of novel devices based on domain wall functionalities. In this work, the introduction of a dielectric layer leads to the tunability of the depolarization field both in the multilayers and superlattices, which provides a novel approach to control the domain patterns of BiFeO3 films. Moreover, we are able to study the switching behavior of the first time obtained periodic 109° stripe domains with a thick bottom electrode. Besides, the precise controlling of pure 71° and 109° periodic stripe domain walls enable us to make a clear demonstration that the exchange bias in the ferromagnet/BiFeO3 system originates from 109° domain walls. Our findings provide future directions to study the room temperature electric field control of exchange bias and open a new pathway to explore the room temperature multiferroic vortices in the BiFeO3 system.

AB - A wealth of fascinating phenomena have been discovered at the BiFeO3 domain walls, examples such as domain wall conductivity, photovoltaic effects, and magnetoelectric coupling. Thus, the ability to precisely control the domain structures and accurately study their switching behaviors is critical to realize the next generation of novel devices based on domain wall functionalities. In this work, the introduction of a dielectric layer leads to the tunability of the depolarization field both in the multilayers and superlattices, which provides a novel approach to control the domain patterns of BiFeO3 films. Moreover, we are able to study the switching behavior of the first time obtained periodic 109° stripe domains with a thick bottom electrode. Besides, the precise controlling of pure 71° and 109° periodic stripe domain walls enable us to make a clear demonstration that the exchange bias in the ferromagnet/BiFeO3 system originates from 109° domain walls. Our findings provide future directions to study the room temperature electric field control of exchange bias and open a new pathway to explore the room temperature multiferroic vortices in the BiFeO3 system.

KW - BiFeO

KW - depolarization field

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KW - multiferroic

KW - superlattices

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