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Defect engineering induced phase competition in BNT-based relaxor ferroelectrics for dielectric energy storage

Dongxu Li, Zhipeng Li, Zong‐Yang Shen, Xuhai Shi, Xiaojun Zeng, You Zhang, Wenqin Luo, Fusheng Song, Chaofeng Wu

2024Journal of Materiomics17 citationsDOIOpen Access PDF

Abstract

Dielectric capacitors are independent in advanced electronics and pulse power systems as an energy storage and conversion medium. However, achieving high energy density at a low electric field remains challenging for dielectric materials to improve the safety of integrated electronic devices. In this work, the strategy of defect engineering-induced phase competition is proposed to improve the polarization behavior and strengthen dielectric temperature stability of (Bi,Na)TiO 3 (BNT)-based relaxor ferroelectric, i.e. , Na 0.325 Sr 0.245 Ba 0.105–1.5 x □ 0.5 x Bi 0.325+ x TiO 3 (NSB 0.105–1.5 x □ 0.5 x B 0.325+ x T) ceramics by changing the ratio of Bi 3+ /Ba 2+ . A high recoverable energy density ( W rec = 3.6 J/cm 3 ) is achieved at a relatively low electric field of 160 kV/cm for x = 0.06 composition together with a high dielectric constant of 3142% ± 15% in a wide temperature range of 30–386 °C, which exceeds other lead-free dielectric ceramics at the same electric field. The results demonstrate that NSB 0.015 □ 0.03 B 0.385 T ceramics are desirable for advanced pulsed power capacitors and will push the development of defect-tuned functionality of dielectric ceramics for energy storage applications. • The effect of ( V Ba ″ − V O ∙ ∙ ) defect dipole-induced phase competition on dielectric/ferroelectric properties are analyzed. • NSB 0.105-1.5 x □ 0.5 x B 0.325+ x T ( x = 0.06) ceramics achieves a high W rec of 3.6 J/cm 3 under low electric field of 160 kV/cm. • NSB 0.105-1.5 x □ 0.5 x B 0.325+ x T ( x = 0.06) ceramics exhibits a high ε r of 3142 (@ 150 °C) with ±15% at 30–386 °C.

Topics & Concepts

Materials scienceDielectricEnergy storageCompetition (biology)Phase (matter)Engineering physicsCondensed matter physicsOptoelectronicsThermodynamicsPhysicsPower (physics)Quantum mechanicsBiologyEcologyFerroelectric and Piezoelectric MaterialsDielectric materials and actuatorsMultiferroics and related materials