Exceptionally High Transduction Coefficient in BaTiO 3-Based Piezoceramic Through Phase Boundary Engineering

Chong Gao, X. Yan, Mupeng Zheng, Xin Gao, K. Zhao, Ling Li, M. Zhu, Y. Hou
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Abstract

Transduction coefficient ( d33 × g33 ) is the core parameter for evaluating piezoelectric energy harvesting materials. However, due to the thermodynamic constraints, the synergistic variation between piezoelectric charge constant ( d33 ) and dielectric constant ( εr ) indeed hinder the further increase of d33 × g33 . Herein, an exceptionally high d33 ×g33 of 13167×10−15m2 /N was achieved in 0.80BaTiO3 -0.10CaTiO3 -0.10BaZrO3 (BC0.1ZT) lead-free solid solution for the first time through a phase boundary engineering strategy. The high d33 × g33 mainly stems from non-synergistic variation of dielectricity and piezoelectricity in a new R-O phase boundary , in which the low εr comes from the increased domain size and reduced domain wall density , while the high configurational sensitivity of the unique domains to external electric field contributed to the high d33 on the left side of polymorphic phase boundary (PPB). Our findings provide an alternative approach for enhanced energy harvesting performance by tracing the strategy of designing phase boundary to decouple d33 and εr .
通过相界工程研究batio3基压电陶瓷的超高转导系数
传导系数(d33 × g33)是评价压电能量收集材料的核心参数。然而,由于热力学约束,压电电荷常数(d33)和介电常数(εr)之间的协同变化确实阻碍了d33 × g33的进一步增加。通过相界工程策略,首次在0.80BaTiO3 -0.10CaTiO3 -0.10BaZrO3 (BC0.1ZT)无铅固溶体中获得了13167×10−15m2 /N的超高d33 ×g33。高的d33 × g33主要来自于新R-O相边界中介电和压电的非协同变化,其中低的εr来自于畴尺寸的增大和畴壁密度的减小,而独特畴对外电场的高构形灵敏度导致了多晶相边界(PPB)左侧的高d33。我们的研究结果通过跟踪设计相位边界来解耦d33和εr的策略,为提高能量收集性能提供了另一种方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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