A novel lead-free relaxor with endotaxial nanostructures for capacitive energy storage

Xiaoyan Dong , Tengfei Hu , Xiaojun Wu , Jie Yin , Zhengqian Fu , Jiagang Wu

SusMat ›› 2024, Vol. 4 ›› Issue (1) : 116 -125.

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SusMat ›› 2024, Vol. 4 ›› Issue (1) : 116 -125. DOI: 10.1002/sus2.174
RESEARCH ARTICLE

A novel lead-free relaxor with endotaxial nanostructures for capacitive energy storage

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Abstract

Dielectric capacitors with a fast charging/discharging rate, high power density, and long-term stability are essential components in modern electrical devices. However, miniaturizing and integrating capacitors face a persistent challenge in improving their energy density (Wrec) to satisfy the specifications of advanced electronic systems and applications. In this work, leveraging phase-field simulations, we judiciously designed a novel lead-free relaxor ferroelectric material for enhanced energy storage performance, featuring flexible distributed weakly polar endotaxial nanostructures (ENs) embedded within a strongly polar fluctuation matrix. The matrix contributes to substantially enhanced polarization under an external electric field, and the randomly dispersed ENs effectively optimize breakdown phase proportion and provide a strong restoring force, which are advantageous in bolstering breakdown strength and minimizing hysteresis. Remarkably, this relaxor ferroelectric system incorporating ENs achieves an exceptionally high Wrec value of 10.3 J/cm3, accompanied by a large energy storage efficiency (η) of 85.4%. This work introduces a promising avenue for designing new relaxor materials capable of capacitive energy storage with exceptional performance characteristics.

Keywords

endotaxial nanostructure / energy storage / lead-free / relaxor ferroelectric

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Xiaoyan Dong, Tengfei Hu, Xiaojun Wu, Jie Yin, Zhengqian Fu, Jiagang Wu. A novel lead-free relaxor with endotaxial nanostructures for capacitive energy storage. SusMat, 2024, 4(1): 116-125 DOI:10.1002/sus2.174

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2023 The Authors. SusMat published by Sichuan University and John Wiley & Sons Australia, Ltd.

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