Local Diverse Polarization Optimized Comprehensive Energy‐Storage Performance in Lead‐Free Superparaelectrics

Chen, Liang; Wang, Na; Zhang, Zhifei; Yu, Huifen; Wu, Jie; Deng, Shiqing; Liu, Hui; Qi, He

doi:10.1002/adma.202205787

Cited by 99 publications

(60 citation statements)

References 42 publications

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“…The enhanced polarization (P max − P r ) can be illustrated on the basis of a simplified Landau-Devonshire ferroelectric theory model. The free energy (G) in different states can be expressed as a function of the polarization (P) as follows: [25,26] 2 4 6…”

Section: Resultsmentioning

confidence: 99%

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Zhao

et al. 2023

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Electrostatic capacitors are emerging as a highly promising technology for large‐scale energy storage applications. However, it remains a significant challenge to improve their energy densities. Here, an effective strategy of introducing non‐isovalent ions into the BiFeO3‐based (BFO) ceramic to improve energy storage capability via delaying polarization saturation is demonstrated. Accordingly, an ultra‐high energy density of up to 7.4 J cm−3 and high efficiency ≈ 81% at 680 kV m−1 are realized, which is one of the best energy storage performances recorded for BFO‐based ceramics. The outstanding comprehensive energy storage performance is attributed to inhibiting the polarization hysteresis resulting from generation ergodic relaxor zone and random field, and generating highly‐delayed polarization saturation with continuously‐increased polarization magnitudes with the electric field of supercritical evolution. The contributions demonstrate that delaying the polarization saturation is a consideration for designing the next generation of lead‐free dielectric materials with ultra‐high energy storage performance.

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Section: Resultsmentioning

confidence: 99%

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Zhao

et al. 2023

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“…Pulse power capacitors are intensively used in microwave communications, hybrid electrical vehicles, medical devices, and other electronic power systems [1][2][3][4]. Lead-free dielectric ceramics, the core components of capacitors, are becoming high-profile energy storage materials owing to their distinctive features of high power density (P D ), ultrafast charge/discharge rate (t 0.9 ), and excellent operation stability [2,5].…”

Section: Introductionmentioning

confidence: 99%

Large Energy Capacitive High-Entropy Lead-Free Ferroelectrics

Chen

et al. 2023

Nano-Micro Lett.

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Advanced lead-free energy storage ceramics play an indispensable role in next-generation pulse power capacitors market. Here, an ultrahigh energy storage density of ~ 13.8 J cm−3 and a large efficiency of ~ 82.4% are achieved in high-entropy lead-free relaxor ferroelectrics by increasing configuration entropy, named high-entropy strategy, realizing nearly ten times growth of energy storage density compared with low-entropy material. Evolution of energy storage performance and domain structure with increasing configuration entropy is systematically revealed for the first time. The achievement of excellent energy storage properties should be attributed to the enhanced random field, decreased nanodomain size, strong multiple local distortions, and improved breakdown field. Furthermore, the excellent frequency and fatigue stability as well as charge/discharge properties with superior thermal stability are also realized. The significantly enhanced comprehensive energy storage performance by increasing configuration entropy demonstrates that high entropy is an effective but convenient strategy to design new high-performance dielectrics, promoting the development of advanced capacitors "Image missing".

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“…Relaxors have shown great promise for superior energy-storage performance, due to slim hysteresis with small remnant polarization ( P r ). Designing Pb-free relaxors containing highly polarizable ions with enhanced local polarization is a prevailing idea expected to achieve enhanced energy-storage properties. ,− Importantly, intrinsic polar structures, including the shapes, sizes, dipole patterns, and volume fraction of polar nanoregions substantially affect the properties. Based on rational chemical element substitution/doping and constructing solid solutions, various strategies, such as domain modification, , superparaelectric state, ,, high-entropy, , and phase structure control, − have been proposed.…”

Section: Introductionmentioning

confidence: 99%

“…Designing Pb-free relaxors containing highly polarizable ions with enhanced local polarization is a prevailing idea expected to achieve enhanced energy-storage properties. ,− Importantly, intrinsic polar structures, including the shapes, sizes, dipole patterns, and volume fraction of polar nanoregions substantially affect the properties. Based on rational chemical element substitution/doping and constructing solid solutions, various strategies, such as domain modification, , superparaelectric state, ,, high-entropy, , and phase structure control, − have been proposed. Furthermore, breakdown strength ( E b ) is also an important parameter, and can be improved through nanostructure construction, , grain refining, electrical microstructure control, , defect engineering, etc.…”

Section: Introductionmentioning

confidence: 99%

Superior Capacitive Energy-Storage Performance in Pb-Free Relaxors with a Simple Chemical Composition

et al. 2023

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Chemical design of lead-free relaxors with simultaneously high energy density (W rec) and high efficiency (η) for capacitive energy-storage has been a big challenge for advanced electronic systems. The current situation indicates that realizing such superior energy-storage properties requires highly complex chemical components. Herein, we demonstrate that, via local structure design, an ultrahigh W rec of 10.1 J/cm3, concurrent with a high η of 90%, as well as excellent thermal and frequency stabilities can be achieved in a relaxor with a very simple chemical composition. By introducing 6s 2 lone pair stereochemical active Bi into the classical BaTiO3 ferroelectric to generate a mismatch between A- and B-site polar displacements, a relaxor state with strong local polar fluctuations can be formed. Through advanced atomic-resolution displacement mapping and 3D reconstructing the nanoscale structure from neutron/X-ray total scattering, it is revealed that the localized Bi enhances the polar length largely at several perovskite unit cells and disrupts the long-range coherent Ti polar displacements, resulting in a slush-like structure with extremely small size polar clusters and strong local polar fluctuations. This favorable relaxor state exhibits substantially enhanced polarization, and minimized hysteresis at a high breakdown strength. This work offers a feasible avenue to chemically design new relaxors with a simple composition for high-performance capacitive energy-storage.

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Local Diverse Polarization Optimized Comprehensive Energy‐Storage Performance in Lead‐Free Superparaelectrics

Cited by 99 publications

References 42 publications

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Large Energy Capacitive High-Entropy Lead-Free Ferroelectrics

Superior Capacitive Energy-Storage Performance in Pb-Free Relaxors with a Simple Chemical Composition

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Local Diverse Polarization Optimized Comprehensive Energy‐Storage Performance in Lead‐Free Superparaelectrics

Cited by 99 publications

References 42 publications

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO3‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO3‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Large Energy Capacitive High-Entropy Lead-Free Ferroelectrics

Superior Capacitive Energy-Storage Performance in Pb-Free Relaxors with a Simple Chemical Composition

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Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions

Delayed Polarization Saturation Induced Superior Energy Storage Capability of BiFeO₃‐Based Ceramics Via Introduction of Non‐Isovalent Ions