Colossal Ferroelectric Photovoltaic Effect in Inequivalent Double-Perovskite Bi<sub>2</sub>FeMnO<sub>6</sub> Thin Films

Liu, Xudong; Tu, Jie; Fang, Yue-Wen; Xi, Guoqiang; Li, Hangren; Wu, Rong; Liu, Xiuqiao; Lu, Dongfei; He, Jiushe; Zhang, Junwei; Tian, Jianjun; Zhang, Linxing

doi:10.1021/jacs.4c01702

J. Am. Chem. Soc.

2024

DOI: 10.1021/jacs.4c01702

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Colossal Ferroelectric Photovoltaic Effect in Inequivalent Double-Perovskite Bi₂FeMnO₆ Thin Films

Xudong Liu,

Jie Tu,

Yue-Wen Fang

et al.

Abstract: Double perovskite films have been extensively studied for ferroelectric order, ferromagnetic order, and photovoltaic effects. The customized ion combinations and ordered ionic arrangements provide unique opportunities for bandgap engineering. Here, a synergistic strategy to induce chemical strain and charge compensation through inequivalent element substitution is proposed. A-site substitution of the barium ion is used to modify the chemical valence and defect density of the two B-site elements in Bi2FeMnO6 do… Show more

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References 88 publications

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Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

Zhang,

Xi,

Fang

et al. 2024

Preprint

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The magnetic ordering of perovskite ferroelectric oxides is essential for enhancing their stability and minimizing energy losses in magnetoelectric devices. However, inducing a transition from a magnetically disordered state to an ordered one remains a formidable challenge. Here, we propose a chemical sulfurization method that significantly bolsters the magnetic ordering of multiferroic super-tetragonal phase BiFeO3 thin film, thereby enhancing the magnetic properties. The sulfured films exhibit a robust magnetic transition temperature of 586 K. The remanent magnetization increases approximately 1.6 times in the out-of-plane direction and an impressive 62 times in the in-plane direction. Additionally, the magnetic easy axis transitions from the out-of-plane to the in-plane direction. The X-ray absorption spectroscopy and atomic scale investigation reveal a reconfiguration of the local electronic hybridization states in the film. The sulfur-induced shear strain is identified as the catalyst for a shift in the Fe–O hybridization, from the pyramid-like geometry of FeO5 to the octahedral arrangement of FeO6. This transformation is deemed the root cause of the observed magnetic transition in the films. This sulfur-induced strategy for electronic hybridization reconfiguration is expected to break new ground, offering innovative methodologies for modulating perovskite oxides, two-dimensional ferroelectric films, and other ferromagnetic functional thin films.

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Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

Zhang,

Xi,

Fang

et al. 2024

Preprint

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Colossal Ferroelectric Photovoltaic Effect in Inequivalent Double-Perovskite Bi₂FeMnO₆ Thin Films

Cited by 1 publication

References 88 publications

Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

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Colossal Ferroelectric Photovoltaic Effect in Inequivalent Double-Perovskite Bi2FeMnO6 Thin Films

Cited by 1 publication

References 88 publications

Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

Shear Strain Control of Multiferroic Magnetic Ordering for Giant Ferromagnetism

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Colossal Ferroelectric Photovoltaic Effect in Inequivalent Double-Perovskite Bi₂FeMnO₆ Thin Films