Integrated sensing and acoustofluidic functions for flexible thin film acoustic wave devices based on metallic and polymer multilayers
Integrated sensing and acoustofluidic functions for flexible thin film acoustic wave devices based on metallic and polymer multilayers
Surface acoustic wave (SAW) devices are generally fabricated on rigid substrates that support the propagation of waves efficiently. Although very challenging, the realisation of SAW devices on bendable and flexible substrates can lead to new generation SAW devices for wearable technologies. In this paper, we report flexible acoustic wave devices based on ZnO thin films coated on various substrates consisting of thin layers of metal (e.g., Ni/Cu/Ni) and/or polymer (e.g., polyethylene terephthalate, PET). We comparatively characterise the fabricated SAW devices and demonstrate their sensing applications for temperature and ultraviolet (UV) light. We also investigate their acoustofluidic capabilities on different substrates. Our results show that the SAW devices fabricated on a polymer layer (e.g. ZnO/PET, ZnO/Ni/Cu/Ni/PET) show enhanced temperature responsivity, and the devices with larger wavelengths are more sensitive to UV exposure. For actuation purposes, the devices fabricated on ZnO/Ni/Cu/Ni layer have the best performance for acoustofluidics, whereas insignificant acoustofluidic effects are observed with the devices fabricated on ZnO/PET layers. We propose that the addition of a metallic layer of Ni/Cu/Ni between ZnO and polymer layers facilitates the actuation capability for the acoustofluidic applications while keeping temperature and UV sensing capabilities, thus enhancing the integration of sensing and acoustofluidic functions.
Acoustic wave, acoustofluidics, bendable, flexible, multilayers, sensing, thin film
Zahertar, Shahrzad
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Tao, Ran
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Wang, Hongzhe
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Torun, Hamdi
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Canyelles-Pericas, Pep
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Liu, Yang
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Vernon, Jethro
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Ng, Wai Pang
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Binns, Richard
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Wu, Qiang
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Luo, Jingting
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Fu, Yong Qing
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Zahertar, Shahrzad
9e9db9c7-0e1e-4d50-99b8-af23e09ab6ae
Tao, Ran
08d40ff6-99d4-4017-9f02-a789ec813496
Wang, Hongzhe
412e439a-f632-4af3-8de3-2ad854278120
Torun, Hamdi
6635ce04-57c2-4847-9cce-67ce2425d32b
Canyelles-Pericas, Pep
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Liu, Yang
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Vernon, Jethro
1d0d0eb4-f741-4acb-86a7-f7236118deb8
Ng, Wai Pang
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Binns, Richard
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Wu, Qiang
fad3844e-9eba-496c-876d-3bbc9ee4a689
Luo, Jingting
402dc9e0-81d7-49cc-b697-e3fbb2e8f760
Fu, Yong Qing
33ef6026-25d5-472b-8ab5-861afb123abd
Zahertar, Shahrzad, Tao, Ran, Wang, Hongzhe, Torun, Hamdi, Canyelles-Pericas, Pep, Liu, Yang, Vernon, Jethro, Ng, Wai Pang, Binns, Richard, Wu, Qiang, Luo, Jingting and Fu, Yong Qing
(2022)
Integrated sensing and acoustofluidic functions for flexible thin film acoustic wave devices based on metallic and polymer multilayers.
IEEE Sensors Journal.
(doi:10.1109/JSEN.2022.3160282).
(In Press)
Abstract
Surface acoustic wave (SAW) devices are generally fabricated on rigid substrates that support the propagation of waves efficiently. Although very challenging, the realisation of SAW devices on bendable and flexible substrates can lead to new generation SAW devices for wearable technologies. In this paper, we report flexible acoustic wave devices based on ZnO thin films coated on various substrates consisting of thin layers of metal (e.g., Ni/Cu/Ni) and/or polymer (e.g., polyethylene terephthalate, PET). We comparatively characterise the fabricated SAW devices and demonstrate their sensing applications for temperature and ultraviolet (UV) light. We also investigate their acoustofluidic capabilities on different substrates. Our results show that the SAW devices fabricated on a polymer layer (e.g. ZnO/PET, ZnO/Ni/Cu/Ni/PET) show enhanced temperature responsivity, and the devices with larger wavelengths are more sensitive to UV exposure. For actuation purposes, the devices fabricated on ZnO/Ni/Cu/Ni layer have the best performance for acoustofluidics, whereas insignificant acoustofluidic effects are observed with the devices fabricated on ZnO/PET layers. We propose that the addition of a metallic layer of Ni/Cu/Ni between ZnO and polymer layers facilitates the actuation capability for the acoustofluidic applications while keeping temperature and UV sensing capabilities, thus enhancing the integration of sensing and acoustofluidic functions.
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Integrated_sensing_and_acoustofluidic_functions_for_flexible_thin_film_acoustic_wave_devices_based_on_metallic_and_polymer_multilayers
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Accepted/In Press date: 2022
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Keywords:
Acoustic wave, acoustofluidics, bendable, flexible, multilayers, sensing, thin film
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Local EPrints ID: 457320
URI: http://eprints.soton.ac.uk/id/eprint/457320
ISSN: 1530-437X
PURE UUID: 4b99231c-36af-4c6e-8846-82ac737eb6ef
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Date deposited: 01 Jun 2022 16:36
Last modified: 17 Mar 2024 04:08
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Contributors
Author:
Ran Tao
Author:
Hongzhe Wang
Author:
Hamdi Torun
Author:
Pep Canyelles-Pericas
Author:
Yang Liu
Author:
Jethro Vernon
Author:
Wai Pang Ng
Author:
Richard Binns
Author:
Qiang Wu
Author:
Jingting Luo
Author:
Yong Qing Fu
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