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Superior Energy Storage Performance in a Self‐Organized Trirelaxor‐Antiferroelectric Nanocomposite Over a Wide Temperature Range

Jingzhe Xu, Yongbin Liu, Dong Wang, He Li, Lisheng Zhong, Jinghui Gao, Ming C. Wu, Ruifeng Yao, Nan Zhang, Xiaojie Lou, Shengtao Li, Xiaobing Ren

2025Advanced Materials10 citationsDOI

Abstract

Abstract A fundamental paradox in energy storage dielectrics lies in the challenge of achieving superior performance consistently across both room and elevated temperatures. This is addressed by designing a self‐organized nanocomposite (1−x)(Ba,Sr)(Ti,Sn)O 3 ‐xBi 1.5 ZnNb 1.5 O 7 composed of nano‐sized antiferroelectric(AFE) particles embedded into a trirelaxor(TRE) matrix through nanoscale phase separation process. The optimal composition at x = 0.11 exhibits outstanding energy storage performance from room temperature (energy density = 8.5 J cm −3 , efficiency = 94.8%, and figure of merit of 167 J cm −3 ) up to 200 °C (energy density = 4.85 J cm −3 , efficiency >90% and figure of merit of 49 J cm −3 ), outperforming existing Pb‐free dielectrics. High‐resolution transmission electron microscopy and synchrotron x‐ray diffractometry reveal that the coexisting nanometric antiferroelectric particles and the trirelaxor nanodomains sustain over a wide temperature range. Piezoresponse force microscopy and phase‐field simulation show that hysteresis‐free switching of trirelaxor nanodomains enables enhanced polarization and low hysteretic loss. Resistivity shows a 2–3 order of magnitude increases accompanying significant increase in breakdown strength up to high temperatures, attributable to deep charge trapping effect at high‐density TRE/AFE interfaces as evidenced by thermally stimulated depolarization current. These favorable effects in the nano‐composite are responsible for its high energy storage performance up to high temperatures.

Topics & Concepts

Materials scienceNanocompositeDielectricAntiferroelectricityHysteresisAtmospheric temperature rangeTransmission electron microscopyNanoscopic scaleFigure of meritPhase (matter)NanotechnologyAnalytical Chemistry (journal)FerroelectricityCondensed matter physicsOptoelectronicsThermodynamicsOrganic chemistryPhysicsChromatographyChemistryFerroelectric and Piezoelectric MaterialsMultiferroics and related materialsDielectric materials and actuators
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