Strain engineering of epitaxial oxide heterostructures beyond substrate limitations

Xiong Deng; Chao Chen; Deyang Chen; Xiangbin Cai; Xiaozhe Yin; Chao Xu; Fei Sun; Caiwen Li; Yan Li; Han Xu; Mao Ye; Guo Tian; Zhen Fan; Zhipeng Hou; Minghui Qin; Yu Chen; Zhenlin Luo; Xubing Lu; Guofu Zhou; Lang Chen; Ning Wang; Ye Zhu; Xingsen Gao; Jun Ming Liu

doi:10.1016/j.matt.2021.02.006

Strain engineering of epitaxial oxide heterostructures beyond substrate limitations

Xiong Deng, Chao Chen, Deyang Chen^*, Xiangbin Cai, Xiaozhe Yin, Chao Xu, Fei Sun, Caiwen Li, Yan Li, Han Xu, Mao Ye, Guo Tian, Zhen Fan, Zhipeng Hou, Minghui Qin, Yu Chen, Zhenlin Luo, Xubing Lu, Guofu Zhou, Lang ChenNing Wang, Ye Zhu, Xingsen Gao, Jun Ming Liu

^*Corresponding author for this work

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

31 Citations (Scopus)

Abstract

Epitaxial strain, imparted by an underlying substrate, is a powerful pathway to drive phase transitions and alter properties in complex oxides, enabling the creation of new ground states and novel functionalities. To realize these emergent phenomena, the availability of appropriate single-crystal substrates for the growth of high-quality epitaxial oxide films with a desired strain state cannot be overemphasized. However, the limitation of commercial substrates and the lack of continuous strain tunability result in stringent restrictions on the further discovery of novel properties and fundamental physics. Here, we propose a strategy for imposing continuously tunable strain beyond substrate limitations by inserting an interface layer, enabling the achievement of continuous orthorhombic–rhombohedral-like–tetragonal-like phase transition in BiFeO₃ films on a single substrate and the integration of morphotropic phase boundary on different substrates. This work provides a framework for the strain engineering of complex oxides.

Original language	English
Pages (from-to)	1323-1334
Number of pages	12
Journal	Matter
Volume	4
Issue number	4
DOIs	https://doi.org/10.1016/j.matt.2021.02.006
Publication status	Published - 7 Apr 2021
Externally published	Yes

Keywords

BiFeO
complex oxides
continuous strain tuning
epitaxial strain
interface
MAP2: Benchmark
morphotropic phase boundary
phase transition

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10.1016/j.matt.2021.02.006

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title = "Strain engineering of epitaxial oxide heterostructures beyond substrate limitations",

abstract = "Epitaxial strain, imparted by an underlying substrate, is a powerful pathway to drive phase transitions and alter properties in complex oxides, enabling the creation of new ground states and novel functionalities. To realize these emergent phenomena, the availability of appropriate single-crystal substrates for the growth of high-quality epitaxial oxide films with a desired strain state cannot be overemphasized. However, the limitation of commercial substrates and the lack of continuous strain tunability result in stringent restrictions on the further discovery of novel properties and fundamental physics. Here, we propose a strategy for imposing continuously tunable strain beyond substrate limitations by inserting an interface layer, enabling the achievement of continuous orthorhombic–rhombohedral-like–tetragonal-like phase transition in BiFeO3 films on a single substrate and the integration of morphotropic phase boundary on different substrates. This work provides a framework for the strain engineering of complex oxides.",

keywords = "BiFeO, complex oxides, continuous strain tuning, epitaxial strain, interface, MAP2: Benchmark, morphotropic phase boundary, phase transition",

author = "Xiong Deng and Chao Chen and Deyang Chen and Xiangbin Cai and Xiaozhe Yin and Chao Xu and Fei Sun and Caiwen Li and Yan Li and Han Xu and Mao Ye and Guo Tian and Zhen Fan and Zhipeng Hou and Minghui Qin and Yu Chen and Zhenlin Luo and Xubing Lu and Guofu Zhou and Lang Chen and Ning Wang and Ye Zhu and Xingsen Gao and Liu, {Jun Ming}",

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year = "2021",

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doi = "10.1016/j.matt.2021.02.006",

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T1 - Strain engineering of epitaxial oxide heterostructures beyond substrate limitations

AU - Deng, Xiong

AU - Chen, Chao

AU - Chen, Deyang

AU - Cai, Xiangbin

AU - Yin, Xiaozhe

AU - Xu, Chao

AU - Sun, Fei

AU - Li, Caiwen

AU - Li, Yan

AU - Xu, Han

AU - Ye, Mao

AU - Tian, Guo

AU - Fan, Zhen

AU - Hou, Zhipeng

AU - Qin, Minghui

AU - Chen, Yu

AU - Luo, Zhenlin

AU - Lu, Xubing

AU - Zhou, Guofu

AU - Chen, Lang

AU - Wang, Ning

AU - Zhu, Ye

AU - Gao, Xingsen

AU - Liu, Jun Ming

PY - 2021/4/7

Y1 - 2021/4/7

N2 - Epitaxial strain, imparted by an underlying substrate, is a powerful pathway to drive phase transitions and alter properties in complex oxides, enabling the creation of new ground states and novel functionalities. To realize these emergent phenomena, the availability of appropriate single-crystal substrates for the growth of high-quality epitaxial oxide films with a desired strain state cannot be overemphasized. However, the limitation of commercial substrates and the lack of continuous strain tunability result in stringent restrictions on the further discovery of novel properties and fundamental physics. Here, we propose a strategy for imposing continuously tunable strain beyond substrate limitations by inserting an interface layer, enabling the achievement of continuous orthorhombic–rhombohedral-like–tetragonal-like phase transition in BiFeO3 films on a single substrate and the integration of morphotropic phase boundary on different substrates. This work provides a framework for the strain engineering of complex oxides.

AB - Epitaxial strain, imparted by an underlying substrate, is a powerful pathway to drive phase transitions and alter properties in complex oxides, enabling the creation of new ground states and novel functionalities. To realize these emergent phenomena, the availability of appropriate single-crystal substrates for the growth of high-quality epitaxial oxide films with a desired strain state cannot be overemphasized. However, the limitation of commercial substrates and the lack of continuous strain tunability result in stringent restrictions on the further discovery of novel properties and fundamental physics. Here, we propose a strategy for imposing continuously tunable strain beyond substrate limitations by inserting an interface layer, enabling the achievement of continuous orthorhombic–rhombohedral-like–tetragonal-like phase transition in BiFeO3 films on a single substrate and the integration of morphotropic phase boundary on different substrates. This work provides a framework for the strain engineering of complex oxides.

KW - BiFeO

KW - complex oxides

KW - continuous strain tuning

KW - epitaxial strain

KW - interface

KW - MAP2: Benchmark

KW - morphotropic phase boundary

KW - phase transition

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DO - 10.1016/j.matt.2021.02.006

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SN - 2590-2393

VL - 4

SP - 1323

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JO - Matter

JF - Matter

IS - 4

ER -

Strain engineering of epitaxial oxide heterostructures beyond substrate limitations

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Keywords

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