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Your search keyword '"Dai, Yejing"' showing total 213 results
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213 results on '"Dai, Yejing"'

1. Large electrobending deformation caused by defect dipoles

Author

Tian, Shuo, Li, Bin, and Dai, Yejing

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Ultrahigh electrostrains (greater than 1%) in several piezoceramic systems have been reported since 2022, which attract more and more interest in the field of piezoelectricity; however, the mechanism is still unclear. Here, we have directly observed a novel electric field-induced bending (electrobending) phenomenon that visually exhibites as an alternating concave-convex deformation under an electric field of plus or minus 50 kV cm-1, in nonstoichiometric (K0.48Na0.52)0.99NbO2.995 ceramics, which causes the measured ultrahigh electrostrain. It is demonstrated that the electrobending deformation arises from the different stresses due to the stretching or compression of the defect dipoles on the upper and lower surfaces of the ceramics. As a result of the large electrobending deformation, a giant apparent electrostrain of 11.6% is obtained at room temperature, and it can even reach up to 26.0% at 210 degree Celsius, which far exceeds that of all present piezoelectric materials. Our discovery is an important addition and refinement to the field of condensed matter physics, whilst providing a new strategy and shedding light on the design of future precision actuators or intelligent devices.

Published
2023

34. Effect of the template particles size on structure and piezoelectric properties of 〈0 0 1〉‐textured BNT‐based ceramics.

Author

Li, Hongtao, Huang, Rongxia, Lin, Hua‐Tay, Du, Zuchao, and Dai, Yejing

Subjects
PIEZOELECTRIC ceramics, LEAD-free ceramics, CERAMICS, SCANNING electron microscopy, X-ray diffractometers
Abstract

This research investigated the effect of Bi4Ti3O12 (BiT) template particles size on the structure and piezoelectric properties of 〈001〉‐textured (Bi0.5Na0.5)TiO3 (BNT)‐based lead‐free piezoelectric ceramics. Results of X‐ray diffractometer analyses and scanning electron microscopy observations showed that high purity BiT template particles could be obtained with the KCl as the molten salt system. Highly 〈001〉‐textured (~87%) BNT‐based ceramics prepared with large size BiT templates (7.75 µm) exhibited a high inverse piezoelectric constant d33* (1100 pm/N), which was ∼3.38‐fold larger than that with 1.91 µm (325 pm/N). In addition, we have found that too small the template size can make it difficult to align the orientation of the template during the casting process, whereas too large the size can create problems such as too much hysteresis (∆S/Smax = 67%). This study has demonstrated that the use of high purity large size BiT template particles could provide a feasible route to fabricate BNT‐based textured ceramics with desired electro‐strain properties. [ABSTRACT FROM AUTHOR]

Published
2024
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44. Enhancement of piezoelectric properties of BF–BT ceramics by using ZrO2 powder bed during the sintering process.

Author

Zhang, Yi, Huang, Rongxia, Zhang, Fan, Liang, Zhihao, Xie, Tianbao, Lin, Hua‐Tay, and Dai, Yejing

Subjects
POWDERS, PIEZOELECTRIC ceramics, CERAMICS, SINTERING, HEAT conduction, DIELECTRIC properties
Abstract

ZrO2 powders of various particle sizes (0.15, 0.7, 500 µm) were used to simulate loose powder bed sintering to prepare BF–BT piezoelectric ceramics. The phase structure, dielectric properties, ferroelectric properties, and piezoelectric properties were compared with the samples sintered by the conventional powder bed method (i.e., powder of the same composition as the sample). Results showed that the use of loose ZrO2 powder bed could improve the heat conduction rate and the sintering quality of bulk BF–BT piezoelectric ceramics. The XPS results showed that the samples sintered with 500 µm ZrO2 powder beds had the lowest concentration of Fe2+, exhibited the largest piezoelectric coefficients (d33 = 201 pC/N). In contrast, the sample sintered with a conventional powder bed under the same sintering conditions had a piezoelectric coefficient d33 of 156 pC/N. [ABSTRACT FROM AUTHOR]

Published
2023
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