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Auteurs principaux: Wang, Tao, Zou, Mingjie, Zhang, Dehe, Ku, Yu-Chieh, Zheng, Yawen, Pan, Shen, Ren, Zhongqi, Xu, Zedong, Huang, Haoliang, Luo, Wei, Tang, Yunlong, Chen, Lang, Liu, Cheng-En, Chang, Chun-Fu, Das, Sujit, Bellaiche, Laurent, Yang, Yurong, Ma, Xiuliang, Kuo, Chang-Yang, Liu, Xingjun, Chen, Zuhuang
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2410.12252
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author Wang, Tao
Zou, Mingjie
Zhang, Dehe
Ku, Yu-Chieh
Zheng, Yawen
Pan, Shen
Ren, Zhongqi
Xu, Zedong
Huang, Haoliang
Luo, Wei
Tang, Yunlong
Chen, Lang
Liu, Cheng-En
Chang, Chun-Fu
Das, Sujit
Bellaiche, Laurent
Yang, Yurong
Ma, Xiuliang
Kuo, Chang-Yang
Liu, Xingjun
Chen, Zuhuang
author_facet Wang, Tao
Zou, Mingjie
Zhang, Dehe
Ku, Yu-Chieh
Zheng, Yawen
Pan, Shen
Ren, Zhongqi
Xu, Zedong
Huang, Haoliang
Luo, Wei
Tang, Yunlong
Chen, Lang
Liu, Cheng-En
Chang, Chun-Fu
Das, Sujit
Bellaiche, Laurent
Yang, Yurong
Ma, Xiuliang
Kuo, Chang-Yang
Liu, Xingjun
Chen, Zuhuang
contents Efforts to combine the advantages of multiple systems to enhance functionlities through solid solution design present a great challenge due to the constraint imposed by the classical Vegard law. Here, we successfully navigate this trade off by leveraging the synergistic effect of chemical doping and strain engineering in solid solution system of BiFeO3 BaTiO3. Unlike bulks, a significant deviation from the Vegard law accompanying with enhanced multiferroism is observed in the strained solid solution epitaxial films, where we achieve a pronounced tetragonality, enhanced saturated magnetization, substantial polarization, high ferroelectric Curie temperature, all while maintaining impressively low leakage current. These characteristics surpass the properties of their parent BiFeO3 and BaTiO3 films. Moreover, the superior ferroelectricity has never been reported in corresponding bulks. These findings underscore the potential of strained BiFeO3 BaTiO3 films as lead-free, room-temperature multiferroics.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12252
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Large Enhancement of Properties in Strained Lead-free Multiferroic Solid Solutions with Strong Deviation from Vegard's Law
Wang, Tao
Zou, Mingjie
Zhang, Dehe
Ku, Yu-Chieh
Zheng, Yawen
Pan, Shen
Ren, Zhongqi
Xu, Zedong
Huang, Haoliang
Luo, Wei
Tang, Yunlong
Chen, Lang
Liu, Cheng-En
Chang, Chun-Fu
Das, Sujit
Bellaiche, Laurent
Yang, Yurong
Ma, Xiuliang
Kuo, Chang-Yang
Liu, Xingjun
Chen, Zuhuang
Materials Science
Efforts to combine the advantages of multiple systems to enhance functionlities through solid solution design present a great challenge due to the constraint imposed by the classical Vegard law. Here, we successfully navigate this trade off by leveraging the synergistic effect of chemical doping and strain engineering in solid solution system of BiFeO3 BaTiO3. Unlike bulks, a significant deviation from the Vegard law accompanying with enhanced multiferroism is observed in the strained solid solution epitaxial films, where we achieve a pronounced tetragonality, enhanced saturated magnetization, substantial polarization, high ferroelectric Curie temperature, all while maintaining impressively low leakage current. These characteristics surpass the properties of their parent BiFeO3 and BaTiO3 films. Moreover, the superior ferroelectricity has never been reported in corresponding bulks. These findings underscore the potential of strained BiFeO3 BaTiO3 films as lead-free, room-temperature multiferroics.
title Large Enhancement of Properties in Strained Lead-free Multiferroic Solid Solutions with Strong Deviation from Vegard's Law
topic Materials Science
url https://arxiv.org/abs/2410.12252