Pyroelectric contributions to piezoelectric hydrostatic Berlincourt method

J. Wooldridge; J. Blackburn; M. De Podesta; M. Stewart; P. Weaver; M. Cain

doi:10.1179/174367509X12472364600959

Pyroelectric contributions to piezoelectric hydrostatic Berlincourt method

J. Wooldridge, J. Blackburn, M. De Podesta, M. Stewart, P. Weaver, M. Cain

National Physical Laboratory

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

Abstract

Piezoelectric materials are used in many applications, at increasingly smaller scales. Methods of measuring their hydrostatic properties have been developed where the piezoelectric charge is produced as a result of a varying hydrostatic pressure generated within a sealed chamber. In this paper, the authors explore an anomalous generation of charge in thin laminar samples and show this is a result of the pyroelectric effect. The authors model the change in temperature in the sealed chamber caused by the adiabatic expansion of the gas and relate this to the observed generation of charge, using finite element modelling to investigate the temperature profile through the material. The implications of these results are relevant for the successful integration of piezoelectric thin and thick films into MEMS devices.

Original language	English
Pages (from-to)	143-146
Number of pages	4
Journal	Advances in Applied Ceramics
Volume	109
Issue number	3
DOIs	https://doi.org/10.1179/174367509X12472364600959
Publication status	Published - 1 Mar 2010
Externally published	Yes

Keywords

Finite element modelling
Piezoelectricity
Pyroelectricity
PZT

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10.1179/174367509X12472364600959

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abstract = "Piezoelectric materials are used in many applications, at increasingly smaller scales. Methods of measuring their hydrostatic properties have been developed where the piezoelectric charge is produced as a result of a varying hydrostatic pressure generated within a sealed chamber. In this paper, the authors explore an anomalous generation of charge in thin laminar samples and show this is a result of the pyroelectric effect. The authors model the change in temperature in the sealed chamber caused by the adiabatic expansion of the gas and relate this to the observed generation of charge, using finite element modelling to investigate the temperature profile through the material. The implications of these results are relevant for the successful integration of piezoelectric thin and thick films into MEMS devices.",

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AU - Blackburn, J.

AU - De Podesta, M.

AU - Stewart, M.

AU - Weaver, P.

AU - Cain, M.

PY - 2010/3/1

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N2 - Piezoelectric materials are used in many applications, at increasingly smaller scales. Methods of measuring their hydrostatic properties have been developed where the piezoelectric charge is produced as a result of a varying hydrostatic pressure generated within a sealed chamber. In this paper, the authors explore an anomalous generation of charge in thin laminar samples and show this is a result of the pyroelectric effect. The authors model the change in temperature in the sealed chamber caused by the adiabatic expansion of the gas and relate this to the observed generation of charge, using finite element modelling to investigate the temperature profile through the material. The implications of these results are relevant for the successful integration of piezoelectric thin and thick films into MEMS devices.

AB - Piezoelectric materials are used in many applications, at increasingly smaller scales. Methods of measuring their hydrostatic properties have been developed where the piezoelectric charge is produced as a result of a varying hydrostatic pressure generated within a sealed chamber. In this paper, the authors explore an anomalous generation of charge in thin laminar samples and show this is a result of the pyroelectric effect. The authors model the change in temperature in the sealed chamber caused by the adiabatic expansion of the gas and relate this to the observed generation of charge, using finite element modelling to investigate the temperature profile through the material. The implications of these results are relevant for the successful integration of piezoelectric thin and thick films into MEMS devices.

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Pyroelectric contributions to piezoelectric hydrostatic Berlincourt method

Abstract

Keywords

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