Loss mechanisms and high power piezoelectrics

K. Uchino; J. H. Zheng; Y. H. Chen; X. H. Du; J. Ryu; Y. Gao; S. Ural; S. Priya; S. Hirose

doi:10.1007/s10853-005-7201-0

Loss mechanisms and high power piezoelectrics

K. Uchino, J. H. Zheng, Y. H. Chen, X. H. Du, J. Ryu, Y. Gao, S. Ural, S. Priya, S. Hirose

Research output: Contribution to journal › Article › peer-review

140 Scopus citations

Abstract

Heat generation is one of the significant problems in piezoelectrics for high power density applications. In this paper, we review the loss mechanisms in piezoelectrics first, followed by the heat generation processes for various drive conditions. Heat generation at off-resonance is caused mainly by dielectric loss tan δ′ (i.e., P-E hysteresis loss), not by mechanical loss, while the heat generation at resonance is mainly attributed to mechanical loss tan φ′. Then, practical high power materials developed at Penn State is introduced, which exhibit the vibration velocity more than 1 m/s, leading to the power density capability 10 times of the commercially available "hard" PZTs. We propose a internal bias field model to explain the low loss and high power origin of these materials. Finally, using a low temperature sinterable "hard" PZT, we demonstrated a high power multilayer piezoelectric transformers.

Original language	English (US)
Pages (from-to)	217-228
Number of pages	12
Journal	Journal of Materials Science
Volume	41
Issue number	1
DOIs	https://doi.org/10.1007/s10853-005-7201-0
State	Published - Jan 2006
Externally published	Yes

Bibliographical note

Funding Information:
Part of this research was supported by the Office of Naval Research through the grant no. N00014-96-1-1173 and N00014-99-1-0754.

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10.1007/s10853-005-7201-0

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title = "Loss mechanisms and high power piezoelectrics",

abstract = "Heat generation is one of the significant problems in piezoelectrics for high power density applications. In this paper, we review the loss mechanisms in piezoelectrics first, followed by the heat generation processes for various drive conditions. Heat generation at off-resonance is caused mainly by dielectric loss tan δ′ (i.e., P-E hysteresis loss), not by mechanical loss, while the heat generation at resonance is mainly attributed to mechanical loss tan φ′. Then, practical high power materials developed at Penn State is introduced, which exhibit the vibration velocity more than 1 m/s, leading to the power density capability 10 times of the commercially available {"}hard{"} PZTs. We propose a internal bias field model to explain the low loss and high power origin of these materials. Finally, using a low temperature sinterable {"}hard{"} PZT, we demonstrated a high power multilayer piezoelectric transformers.",

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note = "Funding Information: Part of this research was supported by the Office of Naval Research through the grant no. N00014-96-1-1173 and N00014-99-1-0754.",

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AU - Uchino, K.

AU - Zheng, J. H.

AU - Chen, Y. H.

AU - Du, X. H.

AU - Ryu, J.

AU - Gao, Y.

AU - Ural, S.

AU - Priya, S.

AU - Hirose, S.

N1 - Funding Information: Part of this research was supported by the Office of Naval Research through the grant no. N00014-96-1-1173 and N00014-99-1-0754.

PY - 2006/1

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N2 - Heat generation is one of the significant problems in piezoelectrics for high power density applications. In this paper, we review the loss mechanisms in piezoelectrics first, followed by the heat generation processes for various drive conditions. Heat generation at off-resonance is caused mainly by dielectric loss tan δ′ (i.e., P-E hysteresis loss), not by mechanical loss, while the heat generation at resonance is mainly attributed to mechanical loss tan φ′. Then, practical high power materials developed at Penn State is introduced, which exhibit the vibration velocity more than 1 m/s, leading to the power density capability 10 times of the commercially available "hard" PZTs. We propose a internal bias field model to explain the low loss and high power origin of these materials. Finally, using a low temperature sinterable "hard" PZT, we demonstrated a high power multilayer piezoelectric transformers.

AB - Heat generation is one of the significant problems in piezoelectrics for high power density applications. In this paper, we review the loss mechanisms in piezoelectrics first, followed by the heat generation processes for various drive conditions. Heat generation at off-resonance is caused mainly by dielectric loss tan δ′ (i.e., P-E hysteresis loss), not by mechanical loss, while the heat generation at resonance is mainly attributed to mechanical loss tan φ′. Then, practical high power materials developed at Penn State is introduced, which exhibit the vibration velocity more than 1 m/s, leading to the power density capability 10 times of the commercially available "hard" PZTs. We propose a internal bias field model to explain the low loss and high power origin of these materials. Finally, using a low temperature sinterable "hard" PZT, we demonstrated a high power multilayer piezoelectric transformers.

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Loss mechanisms and high power piezoelectrics

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