Your search keyword '"Breckner A"' showing total 6 results

1. Engineering dislocation‐rich plastic zones in ceramics via room‐temperature scratching

Author

Fang, Xufei, primary, Preuß, Oliver, additional, Breckner, Patrick, additional, Zhang, Jiawen, additional, and Lu, Wenjun, additional

Published

2023

2. Engineering dislocation‐rich plastic zones in ceramics via room‐temperature scratching

Author

Xufei Fang, Oliver Preuß, Patrick Breckner, Jiawen Zhang, and Wenjun Lu

Subjects

Materials Chemistry, Ceramics and Composites

Published

2023

3. Anisotropy of the high‐power piezoelectric properties of Pb(Zr,Ti)O 3

Author

Kentaro Nakamura, Daniel Isaia, Michael T. Weber, Jiang Wu, Patrick Breckner, Mihail Slabki, and Jurij Koruza

Subjects

010302 applied physics, Coupling, Materials science, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, 01 natural sciences, Piezoelectricity, Vibration, Transverse plane, Normal mode, Heat generation, Electric field, 0103 physical sciences, Materials Chemistry, Ceramics and Composites, 0210 nano-technology, Anisotropy

Abstract

Piezoceramics are widely‐used in high‐power applications, whereby the material is driven in the vicinity of the resonance frequency with high electric fields. Evaluating material's performance at these conditions requires the consideration of inherent nonlinearity, anisotropy, and differences between individual vibration modes. In this work, the relation between electromechanical properties at large vibration velocity and the utilized vibration mode is investigated for a prototype hard piezoceramic. The nonlinear behavior is determined using a combined three‐stage pulse drive method, which enables the analysis of resonant and antiresonant conditions and the calculation of electromechanical parameters. The deviations of coupling coefficients, compliances, and piezoelectric coefficients at high‐power drive were found to be strongest for the transverse length vibration mode. Differences in the mechanical quality factors were observed only between the planar and transverse length modes, which were rationalized by the different strain distribution profiles and the contribution of different loss tensor components. In addition, the influence of the measurement configuration was investigated and a correction method is proposed. The differences between vibration modes are further confirmed by heat generation measurements under continuous drive, which revealed that the strongest heat generation appears in the radial mode, while transverse and longitudinal length modes show similar temperature increase.

Published

2019

4. Anisotropy of the high‐power piezoelectric properties of Pb(Zr,Ti)O 3

Author

Slabki, Mihail, primary, Wu, Jiang, additional, Weber, Michael, additional, Breckner, Patrick, additional, Isaia, Daniel, additional, Nakamura, Kentaro, additional, and Koruza, Jurij, additional

Published

2019

5. Anisotropy of the high‐power piezoelectric properties of Pb(Zr,Ti)O3.

Author

Slabki, Mihail, Wu, Jiang, Weber, Michael, Breckner, Patrick, Isaia, Daniel, Nakamura, Kentaro, and Koruza, Jurij

Subjects

LEAD oxides, ELECTROMECHANICAL effects, ANISOTROPY, CALORIMETRY, QUALITY factor, ELECTRIC fields, INDIVIDUAL differences

Abstract

Piezoceramics are widely‐used in high‐power applications, whereby the material is driven in the vicinity of the resonance frequency with high electric fields. Evaluating material's performance at these conditions requires the consideration of inherent nonlinearity, anisotropy, and differences between individual vibration modes. In this work, the relation between electromechanical properties at large vibration velocity and the utilized vibration mode is investigated for a prototype hard piezoceramic. The nonlinear behavior is determined using a combined three‐stage pulse drive method, which enables the analysis of resonant and antiresonant conditions and the calculation of electromechanical parameters. The deviations of coupling coefficients, compliances, and piezoelectric coefficients at high‐power drive were found to be strongest for the transverse length vibration mode. Differences in the mechanical quality factors were observed only between the planar and transverse length modes, which were rationalized by the different strain distribution profiles and the contribution of different loss tensor components. In addition, the influence of the measurement configuration was investigated and a correction method is proposed. The differences between vibration modes are further confirmed by heat generation measurements under continuous drive, which revealed that the strongest heat generation appears in the radial mode, while transverse and longitudinal length modes show similar temperature increase. Piezoceramics are widely‐used in high‐power applications, whereby the material is driven in the vicinity of the resonance frequency with high electric fields. Evaluating material's performance at these conditions requires the consideration of inherent nonlinearity, anisotropy, and differences between individual vibration modes. In this work, the relation between electromechanical properties at large vibration velocity and the utilized vibration mode is investigated for a prototype hard piezoceramic. The nonlinear behavior is determined using a combined three‐stage pulse drive method, which enables the analysis of resonant and antiresonant conditions and the calculation of electromechanical parameters. The deviations of coupling coefficients, compliances, and piezoelectric coefficients at high‐power drive were found to be strongest for the transverse length vibration mode. Differences in the mechanical quality factors were observed only between the planar and transverse length modes, which were rationalized by the different strain distribution profiles and the contribution of different loss tensor components. In addition, the influence of the measurement configuration was investigated and a correction method is proposed. The differences between vibration modes are further confirmed by heat generation measurements under continuous drive, which revealed that the strongest heat generation appears in the radial mode, while transverse and longitudinal length modes show similar temperature increase. [ABSTRACT FROM AUTHOR]

Published

2019

6. Anisotropy of the high‐power piezoelectric properties of Pb(Zr,Ti)O3.

Author

Slabki, Mihail, Wu, Jiang, Weber, Michael, Breckner, Patrick, Isaia, Daniel, Nakamura, Kentaro, and Koruza, Jurij

Subjects

*LEAD oxides, *ELECTROMECHANICAL effects, *ANISOTROPY, *CALORIMETRY, *QUALITY factor, *ELECTRIC fields, *INDIVIDUAL differences

Abstract

Piezoceramics are widely‐used in high‐power applications, whereby the material is driven in the vicinity of the resonance frequency with high electric fields. Evaluating material's performance at these conditions requires the consideration of inherent nonlinearity, anisotropy, and differences between individual vibration modes. In this work, the relation between electromechanical properties at large vibration velocity and the utilized vibration mode is investigated for a prototype hard piezoceramic. The nonlinear behavior is determined using a combined three‐stage pulse drive method, which enables the analysis of resonant and antiresonant conditions and the calculation of electromechanical parameters. The deviations of coupling coefficients, compliances, and piezoelectric coefficients at high‐power drive were found to be strongest for the transverse length vibration mode. Differences in the mechanical quality factors were observed only between the planar and transverse length modes, which were rationalized by the different strain distribution profiles and the contribution of different loss tensor components. In addition, the influence of the measurement configuration was investigated and a correction method is proposed. The differences between vibration modes are further confirmed by heat generation measurements under continuous drive, which revealed that the strongest heat generation appears in the radial mode, while transverse and longitudinal length modes show similar temperature increase. Piezoceramics are widely‐used in high‐power applications, whereby the material is driven in the vicinity of the resonance frequency with high electric fields. Evaluating material's performance at these conditions requires the consideration of inherent nonlinearity, anisotropy, and differences between individual vibration modes. In this work, the relation between electromechanical properties at large vibration velocity and the utilized vibration mode is investigated for a prototype hard piezoceramic. The nonlinear behavior is determined using a combined three‐stage pulse drive method, which enables the analysis of resonant and antiresonant conditions and the calculation of electromechanical parameters. The deviations of coupling coefficients, compliances, and piezoelectric coefficients at high‐power drive were found to be strongest for the transverse length vibration mode. Differences in the mechanical quality factors were observed only between the planar and transverse length modes, which were rationalized by the different strain distribution profiles and the contribution of different loss tensor components. In addition, the influence of the measurement configuration was investigated and a correction method is proposed. The differences between vibration modes are further confirmed by heat generation measurements under continuous drive, which revealed that the strongest heat generation appears in the radial mode, while transverse and longitudinal length modes show similar temperature increase. [ABSTRACT FROM AUTHOR]

Published

2019