Continuously controllable photoconductance in freestanding BiFeO3 by the macroscopic flexoelectric effect

Guo, Rui; You, Lü; Lin, Weinan; Abdelsamie, Amr; Shu, Xinyu; Zhou, Guowei; Liu, Liang; Yan, Xiaobing; Wang, Junling; Chen, Jingsheng

doi:10.1038/s41467-020-16465-5

Cited by 118 publications

(100 citation statements)

References 37 publications

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“…The enhancement of E b can be explained by the fact that a depolarization electric field at the 2–2 type interfaces between BTO layers and PVDF layers inhibits the mobile charges across interfaces, which is confirmed by phase‐field simulations. In future cases, the preparation process is also applicable to develop a series of 2–2 type composites interlayered by single‐crystal perovskite films, such as SrTiO 3 , [ 64 ] BiFeO 3 , [ 65 ] etc. This kind of composite can further enhance the U further and may be applied in electronics and electrical power systems.…”

Section: Discussionmentioning

confidence: 99%

2–2 Type PVDF‐Based Composites Interlayered by Epitaxial (111)‐Oriented BTO Films for High Energy Storage Density

Tian

Peng

et al. 2021

Adv Funct Materials

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Quick charge/discharge polymer‐based composites filled with inorganic nanosheets have attracted extensive attention and provided a more efficient way to achieve high energy storage density (U) because of the alleviated agglomeration of fillers and the formation of conduction barriers. However, conductive paths have a chance to extend along out‐of‐plane directions by circumventing the micrometer‐sized nanosheets. Here, large‐sized (111)‐oriented BaTiO3 (BTO) films with outstanding epitaxiality and ferroelectricity are embedded in poly(vinylidene fluoride) (PVDF) using optimal transfer and hot‐pressing processes. The 2D–2D (2–2) type BTO/PVDF composites interlayered by 2‐layer BTO (about 0.2 µm thick of each layer) exhibit the highest U of 20.7 J cm‐3 at 690 MV m‐1, which is 222.6% that of pure PVDF. Phase‐field simulations reveal that high‐resistance PVDF films as outer layers can prevent the charges injection from electrodes and high‐dielectric BTO films as inner layers can effectively suppress the mobile charges across interfaces between layers, leading to a remarkable improvement of breakdown strength. This work puts forward a scalable approach to enhance the U of inorganic/organic composites for advanced energy storage materials and applications.

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Section: Discussionmentioning

confidence: 99%

2–2 Type PVDF‐Based Composites Interlayered by Epitaxial (111)‐Oriented BTO Films for High Energy Storage Density

Tian

Peng

et al. 2021

Adv Funct Materials

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“…For example, Chu et al [21] observed a significant strain gradient-induced enhancement of photocurrent at the morphotropic phase boundaries (MPBs) in mixed-phase BiFeO 3 (BFO) films. In addition, Guo et al [22] demonstrated the Flexoelectricity has become an emerging tool to tailor the material properties. The flexoelectric modulation of ferroelectric photovoltaic (FEPV) properties is of particular interest, because it offers an opportunity to boost the photovoltaic efficiency.…”

Section: Significant Modulation Of Ferroelectric Photovoltaic Behavior By a Giant Macroscopic Flexoelectric Effect Induced By Strain-relamentioning

confidence: 99%

Significant Modulation of Ferroelectric Photovoltaic Behavior by a Giant Macroscopic Flexoelectric Effect Induced by Strain‐Relaxed Epitaxy

Huang

Fan

Rao

et al. 2021

Adv Elect Materials

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Flexoelectricity has become an emerging tool to tailor the material properties. The flexoelectric modulation of ferroelectric photovoltaic (FEPV) properties is of particular interest, because it offers an opportunity to boost the photovoltaic efficiency. In most previous studies, the flexoelectric effect is generated by local pressing or macroscopic bending, which, however, results in a local or weak modulation of the FEPV behavior. Here, a significant modulation of the FEPV effect by the strain‐relaxed epitaxy (SRE)‐induced giant macroscopic flexoelectric effect is demonstrated. Using SRE, giant strain gradients (>107 m−1) are generated and tuned in ferroelectric Pb(Zr0.2Ti0.8)O3 epitaxial films. Tuning the giant strain gradient can significantly modify the switchable FEPV properties. Particularly, a photovoltage enhancement as large as ≈0.5 V is achieved. It is suggested that the flexoelectric modulation of FEPV behavior may originate from the flexoelectric polarization‐induced depolarization field. This study highlights the immense application potential of the SRE‐induced flexoelectricity in the engineering of functional thin‐film devices.

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“…In contrast, flexoelectricity, the coupling between an electric polarization and strain gradient, [ 11 , 12 , 13 , 14 , 15 ] has been demonstrated in recent studies on various material systems to modulate physical properties, for example, a photovoltaic effect, Schottky barrier, resistance, or polarization, has been reported in BiFeO 3 , [ 16 ] halide perovskite, [ 17 ] Si, [ 18 ] TiO 2 , [ 18 , 19 ] and (Nb‐)SrTiO 3 , [ 14 , 15 , 18 , 19 ] to name a few. Basically, flexoelectricity is a universal property of all dielectric materials including centrosymmetric materials, which occurs under an inhomogeneous strain field.…”

Section: Introductionmentioning

confidence: 99%

Mixed Triboelectric and Flexoelectric Charge Transfer at the Nanoscale

et al. 2021

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The triboelectric effect is a ubiquitous phenomenon in which the surfaces of two materials are easily charged during the contact-separation process. Despite the widespread consequences and applications, the charging mechanisms are not sufficiently understood. Here, the authors report that, in the presence of a strain gradient, the charge transfer is a result of competition between flexoelectricity and triboelectricity, which could enhance charge transfer during triboelectric measurements when the charge transfers of both effects are in the same direction. When they are in the opposite directions, the direction and amount of charge transfer could be modulated by the competition between flexoelectric and triboelectric effects, which leads to a distinctive phenomenon, that is, the charge transfer is reversed with varying forces. The subsequent results on the electrical power output signals from the triboelectrification support the proposed mechanism. Therefore, the present study emphasizes the key role of the flexoelectric effect through experimental approaches, and suggests that both the amount and direction of charge transfer can be modulated by manipulating the mixed triboelectric and flexoelectric effects. This finding may provide important information on the triboelectric effect and can be further extended to serve as a guideline for material selection during a nanopatterned device design.

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Continuously controllable photoconductance in freestanding BiFeO3 by the macroscopic flexoelectric effect

Cited by 118 publications

References 37 publications

2–2 Type PVDF‐Based Composites Interlayered by Epitaxial (111)‐Oriented BTO Films for High Energy Storage Density

2–2 Type PVDF‐Based Composites Interlayered by Epitaxial (111)‐Oriented BTO Films for High Energy Storage Density

Significant Modulation of Ferroelectric Photovoltaic Behavior by a Giant Macroscopic Flexoelectric Effect Induced by Strain‐Relaxed Epitaxy

Mixed Triboelectric and Flexoelectric Charge Transfer at the Nanoscale

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