Piezoelectric Boundary and Surface Waves Propagating on Glass Film/ZnO Film/Glass Substrate Structures

Shoji FURUKAWA; Takashi NIINO; Tooru NOMURA; Tsutomu YASUDA

Piezoelectric Boundary and Surface Waves Propagating on Glass Film/ZnO Film/Glass Substrate Structures

Shoji FURUKAWA, Takashi NIINO, Tooru NOMURA, Tsutomu YASUDA

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Piezoelectric acoustic waves propagating on glass film/ZnO film/glass substrate structures are theoretically studied. When the thickness of the overgrowth glass film is thin, there exist only the surface waves similar to the Rayleigh waves propagating on ZnO/glass structures. With increasing the overgrowth thickness, there appear the boundary waves, whose particle displacement and electric potential become large at the ZnO layer. The velocity dispersion (velocity vs. ZnO thickness) curve changes very much with increasing the glass thickness, and there appear both dispersive and non-dispersive regions, which correspond to the boundary and surface waves, respectively.

Publication: IEICE TRANSACTIONS on Fundamentals Vol.E74-A No.8 pp.2184-2187

Publication Date: 1991/08/25

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Type of Manuscript: LETTER

Category: Nonlinear Phenomena and Analysis

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Shoji FURUKAWA
Takashi NIINO
Tooru NOMURA
Tsutomu YASUDA

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Shoji FURUKAWA, Takashi NIINO, Tooru NOMURA, Tsutomu YASUDA, "Piezoelectric Boundary and Surface Waves Propagating on Glass Film/ZnO Film/Glass Substrate Structures" in IEICE TRANSACTIONS on Fundamentals, vol. E74-A, no. 8, pp. 2184-2187, August 1991, doi: .
Abstract: Piezoelectric acoustic waves propagating on glass film/ZnO film/glass substrate structures are theoretically studied. When the thickness of the overgrowth glass film is thin, there exist only the surface waves similar to the Rayleigh waves propagating on ZnO/glass structures. With increasing the overgrowth thickness, there appear the boundary waves, whose particle displacement and electric potential become large at the ZnO layer. The velocity dispersion (velocity vs. ZnO thickness) curve changes very much with increasing the glass thickness, and there appear both dispersive and non-dispersive regions, which correspond to the boundary and surface waves, respectively.
URL: https://global.ieice.org/en_transactions/fundamentals/10.1587/e74-a_8_2184/_p

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@ARTICLE{e74-a_8_2184,
author={Shoji FURUKAWA, Takashi NIINO, Tooru NOMURA, Tsutomu YASUDA, },
journal={IEICE TRANSACTIONS on Fundamentals},
title={Piezoelectric Boundary and Surface Waves Propagating on Glass Film/ZnO Film/Glass Substrate Structures},
year={1991},
volume={E74-A},
number={8},
pages={2184-2187},
abstract={Piezoelectric acoustic waves propagating on glass film/ZnO film/glass substrate structures are theoretically studied. When the thickness of the overgrowth glass film is thin, there exist only the surface waves similar to the Rayleigh waves propagating on ZnO/glass structures. With increasing the overgrowth thickness, there appear the boundary waves, whose particle displacement and electric potential become large at the ZnO layer. The velocity dispersion (velocity vs. ZnO thickness) curve changes very much with increasing the glass thickness, and there appear both dispersive and non-dispersive regions, which correspond to the boundary and surface waves, respectively.},
keywords={},
doi={},
ISSN={},
month={August},}

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TY - JOUR
TI - Piezoelectric Boundary and Surface Waves Propagating on Glass Film/ZnO Film/Glass Substrate Structures
T2 - IEICE TRANSACTIONS on Fundamentals
SP - 2184
EP - 2187
AU - Shoji FURUKAWA
AU - Takashi NIINO
AU - Tooru NOMURA
AU - Tsutomu YASUDA
PY - 1991
DO -
JO - IEICE TRANSACTIONS on Fundamentals
SN -
VL - E74-A
IS - 8
JA - IEICE TRANSACTIONS on Fundamentals
Y1 - August 1991
AB - Piezoelectric acoustic waves propagating on glass film/ZnO film/glass substrate structures are theoretically studied. When the thickness of the overgrowth glass film is thin, there exist only the surface waves similar to the Rayleigh waves propagating on ZnO/glass structures. With increasing the overgrowth thickness, there appear the boundary waves, whose particle displacement and electric potential become large at the ZnO layer. The velocity dispersion (velocity vs. ZnO thickness) curve changes very much with increasing the glass thickness, and there appear both dispersive and non-dispersive regions, which correspond to the boundary and surface waves, respectively.
ER -