High‐performance ferroelectric based materials via high‐entropy strategy: Design, properties, and mechanism

High‐performance ferroelectric materials are widely used in various electronic devices owing to the function of mutual conversion among different energies, which mainly relates to their special structure gene of polarization configuration. Recent researches show that the high‐entropy strategy has em...

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Bibliographic Details
Published in:InfoMat 2023-12, Vol.5 (12), p.n/a
Main Authors: Zhang, Yueyun, Chen, Liang, Liu, Hui, Deng, Shiqing, Qi, He, Chen, Jun
Format: Article
Language:English
Subjects:
Configuration management
Copyright
Dielectric properties
Electric fields
Electrical properties
Electrostriction
Energy storage
Entropy
Ferroelectric materials
Ferroelectricity
high performance
high‐entropy design
local structure
Mechanical properties
Phase transitions
Physical properties
Piezoelectricity
Polarization
polarization configuration
Single crystals
Symmetry
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Summary:High‐performance ferroelectric materials are widely used in various electronic devices owing to the function of mutual conversion among different energies, which mainly relates to their special structure gene of polarization configuration. Recent researches show that the high‐entropy strategy has emerged as an effective and flexible approach for boosting physical properties in high‐entropy ferroelectrics via the delicate design of local polarization configurations and other intrinsic effects caused by entropy increment, such as entropy stabilization, lattice disorder, inhibition of grain coarsening, improved mechanical properties, cocktail effect, and so on. In this review, the recent research progress about high‐entropy ferroelectrics has been summarized, especially for the directional design of novel local polarization configurations according to the characteristics of different electrical properties such as high piezoelectricity, high‐efficiency energy storage, and large electrostriction, providing a guidance for designing and exploring more novel local polarization configurations in high‐entropy ferroelectrics for generating higher performance. High‐entropy ferroelectric‐based materials are designed by considering the matrix structure, types, and content of alien atoms as well as their adjustment on the ferroic functional cells at the same time, which not only exhibit high‐entropy effects caused by the substitution of multiple elements but also have tunable ferroic functional cells through fully considering the matrix structure and the characteristics of alien atoms.
ISSN:2567-3165
2567-3165
DOI:10.1002/inf2.12488