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Polar Vortices in Relaxor Ferroelectric Ceramics for High-Efficiency Capacitive Energy Storage

Fangling Chen, Mo Chen, Jingji Zhang, Wei-Shen Liu, Huiwei Du, Quan Zong, Huanan Yu, Yang Zhang, Jigong Hao, Jiangying Wang, Jiwei Zhai

2025ACS Nano72 citationsDOI

Abstract

Polar vortices are predominantly observed within the confined ferroelectric films and the ferroelectric/paraelectric superlattices. This raises the intriguing question of whether polar vortices can form within relaxor ferroelectric ceramics and subsequently contribute to their energy storage performances. Here, we incorporate 10 mol % CaSnO 3 into the 0.7NaNbO 3 -0.3Sr 0.7 Bi 0.2 TiO 3 matrix, yielding a coexistence of phases: 48.8% orthorhombic P 2 1 / ma, 49.1% tetragonal P 4 bm, and 2.1% tetragonal P 4 2 / mnm SnO 2, which is confirmed by the combination of X-ray diffraction and transmission electron microscopy. The ceramic features a pronounced core–shell structure with the shell region rich in stripe nanoscale domains of the P 2 1 / ma phase and the core region consisting of polar nanoregions deficient in the P 2 1 / ma phase, forming polar vortices. Consequently, the ceramic achieves an impressive recoverable energy storage density of 6.83 J cm –3 and an exceptional efficiency of 95.7% at a high breakdown strength of 750 kV cm –1, along with superior stability in frequency, temperature, and cycling. These results not only offer a viable approach for developing high-performance energy storage ceramics through the controlled formation of polar vortices but also offer the potential for direct electric-field control of polar vortices for high-speed data processing and storage.

Topics & Concepts

Materials scienceVortexPolarCapacitive sensingFerroelectricityEnergy storageCeramicRelaxor ferroelectricCondensed matter physicsFerroelectric ceramicsNanotechnologyPolar vortexOptoelectronicsEngineering physicsDielectricComposite materialElectrical engineeringThermodynamicsPhysicsPower (physics)AstronomyEngineeringDielectric materials and actuatorsFerroelectric and Piezoelectric MaterialsAdvanced Sensor and Energy Harvesting Materials
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