期刊
JOURNAL OF THE EUROPEAN CERAMIC SOCIETY
卷 42, 期 3, 页码 944-953出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.jeurceramsoc.2021.11.037
关键词
Electrostriction; Strain; Ferroelectric; KNN; Ceramics
资金
- National Natural Science Foundation of China [52172127, 51772239, 51761145024]
- Fundamental Research Funds for the Central Universities (XJTU)
This research clarifies the electrostrictive effect in KNN-based systems, demonstrating that the Q(33) values in the KNLN-ST system fall within a reasonable range for perovskite-structured ferroelectric ceramics. Furthermore, an ultra-high electrostrictive strain was achieved in the 0.8KNLN-0.2ST sample, expanding the potential application field of KNN-based ceramics to electrostrictive actuators.
The longitudinal electrostrictive coefficient Q(33 )for perovskite-structured ferroelectric ceramics is usually between 0.01-0.04 m(4)/C-2. However, an ultra-low Q(33) of only 0.0047 m(4)/C-2 was identified in the 0.9K(0.)(5)Na(0.)(5)NbO(3)-0.1SrTiO(3) (KNN-ST) composition. Despite the fact that superior piezoelectricity has been observed in KNN-based ceramics, this value is obviously much smaller than the normal value, according to the general cognition and the thermodynamic relationship between piezoelectric coefficient d(33) and Q(33). Therefore, we synthesized (1-x)(K0.45Na0.49Li0.06)NbO3-xSrTiO(3) (KNLN-ST) and studied phase structure, dielectric and ferroelectric properties systematically. Our findings show that the Q(33) in the KNLN-ST system (0.012-0.027 m(4)/ C-2) is within the reasonable range for perovskite-structured ferroelectric ceramics. Furthermore, an ultra-high electrostrictive strain (>0.3%) with ultra-low hysteresis was achieved in the 0.8KNLN-0.2ST sample. This research not only clarifies the electrostrictive effect in KNN-based systems, but it also broadens the potential application field of KNN-based ceramics to electrostrictive actuators.
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