Simple isovalent substitution route enhancing energy storage performance of linear dielectric ceramics

IF 6.3 2区材料科学 Q2 CHEMISTRY, PHYSICAL

Journal of Alloys and Compounds Pub Date : 2025-01-28 DOI:10.1016/j.jallcom.2025.178906

Jiyu Zhao, Mankang Zhu, Yexin Li, Mupeng Zheng, Yudong Hou

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引用次数: 0

Abstract

Linear dielectrics get wide attention in the field of high-voltage dielectric energy storage due to their high electrical breakdown resistance; but its low polarization feature inherited from the quasi-elastic ionic polarization limits their practicality. A simple isovalent substitution route enhancing the field-induced polarization and energy storage performance of linear dielectric Sr_0.65Ca_0.35Zr_0.875Ti_0.125O₃ ceramics was put forward in this study. By incorporating 20 mol.% Ba^2 + cations in A-site, sample Ba_0.2(Sr_0.65Ca_0.35)_0.8Zr_0.875Ti_0.125O₃ realizes a high recoverable energy density of 3.40 J/cm³ and high efficiency over 90 %, accompanied with excellent temperature stability. The introduced Ba²⁺ cations promote the orthorhombic and pseudo-cubic coexistence and reduce the lattice transition energy, which enhance the field-induced polarization while keeping the linear dielectric nature. This simple isovalent substitution route provides important insights into improving the field-induced polarization of a linear dielectric.

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提高线性介质陶瓷储能性能的简单等价取代途径

线性介质因其耐击穿性能好而在高压介质储能领域受到广泛关注；但它继承了准弹性离子极化的低极化特性，限制了其实用性。本文提出了一种提高线性介质Sr0.65Ca0.35Zr0.875Ti0.125O3陶瓷场致极化和储能性能的简单等价取代方法。样品Ba0.2(Sr0.65Ca0.35)0.8Zr0.875Ti0.125O3可回收能量密度高达3.40 J/cm3，效率高达90%以上，并具有良好的温度稳定性。引入Ba2+促进了正交态和拟立方态共存，降低了晶格跃迁能，在保持线性介电性质的同时增强了场致极化。这种简单的等价取代途径为改善线性电介质的场致极化提供了重要的见解。

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来源期刊

Journal of Alloys and Compounds 工程技术-材料科学：综合

CiteScore

11.10

自引率

14.50%

发文量

5146

审稿时长

67 days

期刊介绍： The Journal of Alloys and Compounds is intended to serve as an international medium for the publication of work on solid materials comprising compounds as well as alloys. Its great strength lies in the diversity of discipline which it encompasses, drawing together results from materials science, solid-state chemistry and physics.