Chemical Design of Pb-Free Relaxors for Giant Capacitive Energy Storage

Dielectric capacitors have captured substantial attention for advanced electrical and electronic systems. Developing dielectrics with high energy density and high storage efficiency is challenging owing to the high compositional diversity and the lack of general guidelines. Herein, we propose a map...

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Veröffentlicht in:	Journal of the American Chemical Society 2023-05, Vol.145 (21), p.11764-11772
Hauptverfasser:	Liu, Hui, Sun, Zheng, Zhang, Ji, Luo, Huajie, Zhang, Qinghua, Yao, Yonghao, Deng, Shiqing, Qi, He, Liu, Jue, Gallington, Leighanne C., Neuefeind, Joerg C., Chen, Jun
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Sprache:	eng
Schlagworte:	ceramics chemical structure cluster chemistry ENERGY STORAGE perovskites polarization
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container_end_page	11772
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container_title	Journal of the American Chemical Society
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creator	Liu, Hui Sun, Zheng Zhang, Ji Luo, Huajie Zhang, Qinghua Yao, Yonghao Deng, Shiqing Qi, He Liu, Jue Gallington, Leighanne C. Neuefeind, Joerg C. Chen, Jun
description	Dielectric capacitors have captured substantial attention for advanced electrical and electronic systems. Developing dielectrics with high energy density and high storage efficiency is challenging owing to the high compositional diversity and the lack of general guidelines. Herein, we propose a map that captures the structural distortion (δ) and tolerance factor (t) of perovskites to design Pb-free relaxors with extremely high capacitive energy storage. Our map shows how to select ferroelectric with large δ and paraelectric components to form relaxors with a t value close to 1 and thus obtaining eliminated hysteresis and large polarization under a high electric breakdown. Taking the Bi0.5Na0.5TiO3-based solid solution as an example, we demonstrate that composition-driven predominant order–disorder characteristic of local atomic polar displacements endows the relaxor with a slushlike structure and strong local polar fluctuations at several nanoscale. This leads to a giant recoverable energy density of 13.6 J cm–3, along with an ultrahigh efficiency of 94%, which is far beyond the current performance boundary reported in Pb-free bulk ceramics. Our work provides a solution through rational chemical design for obtaining Pb-free relaxors with outstanding energy-storage properties.
doi_str_mv	10.1021/jacs.3c02811
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Developing dielectrics with high energy density and high storage efficiency is challenging owing to the high compositional diversity and the lack of general guidelines. Herein, we propose a map that captures the structural distortion (δ) and tolerance factor (t) of perovskites to design Pb-free relaxors with extremely high capacitive energy storage. Our map shows how to select ferroelectric with large δ and paraelectric components to form relaxors with a t value close to 1 and thus obtaining eliminated hysteresis and large polarization under a high electric breakdown. Taking the Bi0.5Na0.5TiO3-based solid solution as an example, we demonstrate that composition-driven predominant order–disorder characteristic of local atomic polar displacements endows the relaxor with a slushlike structure and strong local polar fluctuations at several nanoscale. This leads to a giant recoverable energy density of 13.6 J cm–3, along with an ultrahigh efficiency of 94%, which is far beyond the current performance boundary reported in Pb-free bulk ceramics. 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Taking the Bi0.5Na0.5TiO3-based solid solution as an example, we demonstrate that composition-driven predominant order–disorder characteristic of local atomic polar displacements endows the relaxor with a slushlike structure and strong local polar fluctuations at several nanoscale. This leads to a giant recoverable energy density of 13.6 J cm–3, along with an ultrahigh efficiency of 94%, which is far beyond the current performance boundary reported in Pb-free bulk ceramics. 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subjects	ceramics chemical structure cluster chemistry ENERGY STORAGE perovskites polarization
title	Chemical Design of Pb-Free Relaxors for Giant Capacitive Energy Storage
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