Litcius/Paper detail

Enhanced energy storage performance and thermal stability in relaxor ferroelectric (1‐x)BiFeO <sub>3</sub> ‐x(0.85BaTiO <sub>3</sub> ‐0.15Bi(Sn <sub>0.5</sub> Zn <sub>0.5</sub> )O <sub>3</sub> ) ceramics

Shuaishuai Ji, Qianjie Li, Dongdong Wang, Jiangyuan Zhu, Min Zeng, Zhipeng Hou, Zhen Fan, Xingsen Gao, Xubing Lu, Qiliang Li, Jun‐Ming Liu

2021Journal of the American Ceramic Society58 citationsDOI

Abstract

Abstract Lead‐free (1‐ x )BiFeO 3 ‐ x (0.85BaTiO 3 ‐0.15Bi(Sn 0.5 Zn 0.5 )O 3 ) [(1‐ x )BF‐ x (BT‐BSZ), x =0.45‐0.7] ceramic samples were prepared by solid phase sintering. It is revealed that the pure single‐phase perovskite structure can be obtained in samples with x ≥ 0.6. With increasing x , the measured ferroelectric hysteresis loop becomes gradually slimmed in accompanying with reduced remnant polarization, and a clear ferroelectric‐relaxor transition at x = 0.65 is identified. Furthermore, the measured electric breakdown strength can be significantly enhanced with increasing x , and the optimal energy storage performance is achieved at x = 0.65, characterized by the recoverable energy storage density up to ≈3.06 J/cm 3 and energy storage efficiency as high as ≈92 %. Excellent temperature stability (25°C–110°C) and fatigue endurance (&gt;10 5 cycles) for energy storage are demonstrated. Our results suggest that the BF‐based relaxor ceramics can be tailored for promising applications in high energy storage devices.

Topics & Concepts

Materials scienceFerroelectricityCeramicEnergy storageHysteresisSinteringThermal stabilityPhase transitionFerroelectric ceramicsPhase (matter)Analytical Chemistry (journal)Condensed matter physicsDielectricThermodynamicsComposite materialOptoelectronicsChemical engineeringChemistryPhysicsOrganic chemistryEngineeringPower (physics)ChromatographyFerroelectric and Piezoelectric MaterialsMultiferroics and related materialsDielectric materials and actuators