High Energy Storage Performance in BiFeO3‐Based Lead‐Free High‐Entropy Ferroelectrics

High Energy Storage Performance in BiFeO3‐Based Lead‐Free High‐Entropy Ferroelectrics

Dielectric capacitors are widely used in advanced electrical and electronic systems due to the rapid charge/discharge rates and high power density. High comprehensive energy storage properties are the ultimate ambition in the field of application achievements. Here, the high‐entropy strategy is prop...

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Published in:Small (Weinheim an der Bergstrasse, Germany) Vol. 20; no. 36; pp. e2400997 - n/a
Main Authors: Wu, Jie, Tan, Hua, Qi, He, Yu, Huifen, Chen, Liang, Li, Wenchao, Chen, Jun
Format: Journal Article
Language:English
Published: Weinheim Wiley Subscription Services, Inc 01-09-2024
Subjects:
BiFeO3
Ceramics
Charge density
Dielectric relaxation
Dielectrics
Discharge
Electronic systems
Energy storage
energy storage properties
Entropy
Ferroelectric materials
Ferroelectricity
Fields (mathematics)
Flux density
Grain refinement
Heterostructures
hierarchical heterostructures
high entropy
lead‐free ceramics
Nanoclusters
Phase transitions
Polarization
Room temperature
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Summary:Dielectric capacitors are widely used in advanced electrical and electronic systems due to the rapid charge/discharge rates and high power density. High comprehensive energy storage properties are the ultimate ambition in the field of application achievements. Here, the high‐entropy strategy is proposed to design and fabricate single‐phase homogeneous (Bi0.5Ba0.1Sr0.1Ca0.2Na0.1)(Fe0.5Ti0.3Zr0.1Nb0.1)O3 ceramic, the hierarchical heterostructure including rhombohedral‐tetragonal multiphase nanoclusters and locally disordered oxygen octahedral tilt can lead to the increased dielectric relaxation, diffused phase transition, diverse local polarization configurations, grain refinement, ultrasmall polar nanoregions, large random field, delayed polarization saturation and improved breakdown field. Accordingly, a giant Wrec ≈13.3 J cm−3 and a high η ≈78% at 66.4 kV mm−1 can be simultaneously achieved in the lead‐free high‐entropy BiFeO3‐based ceramic, showing an obvious advantage in overall energy‐storage properties over BiFeO3‐based lead‐free ceramics. Moreover, an ultrafast discharge rate (t0.9 = 18 ns) can be achieved at room temperature, concomitant with favorable temperature stability in the range of 20–160 °C, due to the enhanced diffuse phase transition and fast polarization response. This work provides a feasible pathway to design and generate dielectric materials exhibiting high comprehensive energy‐storage performance. The introduction of high‐entropy strategy into BiFeO3 can adjust the structural gene cells (such as polarization configurations and oxygen octahedral tilts in ferroelectrics) and generate diverse local polarization configurations, providing the basic for high energy storage properties. This work achieves breakthroughs in the comprehensive energy storage performance for lead‐free BiFeO3‐based ceramics.
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ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202400997