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Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters

Thin film piezoelectric materials play an essential role in micro electro mechanical system (MEMS) energy harvesting due to its low power requirement and high available energy densities. Non-ferroelectric piezoelectric materials such as ZnO and AlN are highly silicon compatible making it suitable fo...

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Main Authors: Md Ralib A.A., Nordin A.N., Salleh H., Othman R.
Other Authors: 36537608500
Format: Conference paper
Published: 2023
Subjects:
Aluminum
Chemical bonds
Design
Electric properties
Energy harvesting
Fabrication
Field emission microscopes
Finite element method
Magnetron sputtering
MEMS
Natural frequencies
Piezoelectric materials
Sensor nodes
Silicon
Thin films
Vapor deposition
X ray diffraction
Zinc oxide
AlN
Available energy density
Chemical batteries
CMOS Compatible
Deposition methods
Electronic functionality
Energy Harvester
Field emission scanning electron microscopy
Finite element modeling
Low Power
Low power wireless
Material characterizations
Open-circuit output voltages
Output voltages
Piezoelectric couplings
Piezoelectric MEMS
Piezoelectric thin films
Power sources
Resonance frequencies
rf-Magnetron sputtering
Self-powered
Silicon substrates
Thin film piezoelectric
Transversal modes
ZnO
Piezoelectricity
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spelling my.uniten.dspace-303052023-12-29T15:46:31Z Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters Md Ralib A.A. Nordin A.N. Salleh H. Othman R. 36537608500 7005958999 24067645400 7003407400 Aluminum Chemical bonds Design Electric properties Energy harvesting Fabrication Field emission microscopes Finite element method Magnetron sputtering MEMS Natural frequencies Piezoelectric materials Sensor nodes Silicon Thin films Vapor deposition X ray diffraction Zinc oxide AlN Available energy density Chemical batteries CMOS Compatible Deposition methods Electronic functionality Energy Harvester Field emission scanning electron microscopy Finite element modeling Low Power Low power wireless Material characterizations Open-circuit output voltages Output voltages Piezoelectric couplings Piezoelectric MEMS Piezoelectric thin films Power sources Resonance frequencies rf-Magnetron sputtering Self-powered Silicon substrates Thin film piezoelectric Transversal modes ZnO Piezoelectricity Thin film piezoelectric materials play an essential role in micro electro mechanical system (MEMS) energy harvesting due to its low power requirement and high available energy densities. Non-ferroelectric piezoelectric materials such as ZnO and AlN are highly silicon compatible making it suitable for MEMS energy harvesters in self-powered microsystems. This work primarily describe the design, simulation and fabrication of aluminium doped zinc oxide (AZO) cantilever beam deposited on <100> silicon substrate. AZO was chosen due its high piezoelectric coupling coefficient, ease of deposition and excellent bonding with silicon substrate. Doping of ZnO with Al has improved the electrical properties, conductivity and thermal stability. The proposed design operates in transversal mode (d31 mode) which was structured as a parallel plated capacitor using Si/Al/AZO/Al layers. The highlight of this work is the successful design and fabrication of Al/AZO/Al on <100> silicon as the substrate to make the device CMOS compatible for electronic functionality integration. Design and finite element modeling was conducted using COMSOL� software to estimate the resonance frequency. RF Magnetron sputtering was chosen as the deposition method for aluminium and AZO. Material characterization was performed using X-ray diffraction and field emission scanning electron microscopy to evaluate the piezoelectric qualities, surface morphology and the cross section. The fabricated energy harvester generated 1.61 V open circuit output voltage at 7.77 MHz resonance frequency. The experimental results agreed with the simulation results. The measured output voltage is sufficient for low power wireless sensor nodes as an alternative power sources to traditional chemical batteries. � Springer-Verlag 2012. Final 2023-12-29T07:46:31Z 2023-12-29T07:46:31Z 2012 Conference paper 10.1007/s00542-012-1550-9 2-s2.0-84870239141 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84870239141&doi=10.1007%2fs00542-012-1550-9&partnerID=40&md5=992dad9656e165659c1b852c2c8d19bf https://irepository.uniten.edu.my/handle/123456789/30305 18 11 1761 1769 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Aluminum
Chemical bonds
Design
Electric properties
Energy harvesting
Fabrication
Field emission microscopes
Finite element method
Magnetron sputtering
MEMS
Natural frequencies
Piezoelectric materials
Sensor nodes
Silicon
Thin films
Vapor deposition
X ray diffraction
Zinc oxide
AlN
Available energy density
Chemical batteries
CMOS Compatible
Deposition methods
Electronic functionality
Energy Harvester
Field emission scanning electron microscopy
Finite element modeling
Low Power
Low power wireless
Material characterizations
Open-circuit output voltages
Output voltages
Piezoelectric couplings
Piezoelectric MEMS
Piezoelectric thin films
Power sources
Resonance frequencies
rf-Magnetron sputtering
Self-powered
Silicon substrates
Thin film piezoelectric
Transversal modes
ZnO
Piezoelectricity
spellingShingle Aluminum
Chemical bonds
Design
Electric properties
Energy harvesting
Fabrication
Field emission microscopes
Finite element method
Magnetron sputtering
MEMS
Natural frequencies
Piezoelectric materials
Sensor nodes
Silicon
Thin films
Vapor deposition
X ray diffraction
Zinc oxide
AlN
Available energy density
Chemical batteries
CMOS Compatible
Deposition methods
Electronic functionality
Energy Harvester
Field emission scanning electron microscopy
Finite element modeling
Low Power
Low power wireless
Material characterizations
Open-circuit output voltages
Output voltages
Piezoelectric couplings
Piezoelectric MEMS
Piezoelectric thin films
Power sources
Resonance frequencies
rf-Magnetron sputtering
Self-powered
Silicon substrates
Thin film piezoelectric
Transversal modes
ZnO
Piezoelectricity
Md Ralib A.A.
Nordin A.N.
Salleh H.
Othman R.
Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
description Thin film piezoelectric materials play an essential role in micro electro mechanical system (MEMS) energy harvesting due to its low power requirement and high available energy densities. Non-ferroelectric piezoelectric materials such as ZnO and AlN are highly silicon compatible making it suitable for MEMS energy harvesters in self-powered microsystems. This work primarily describe the design, simulation and fabrication of aluminium doped zinc oxide (AZO) cantilever beam deposited on <100> silicon substrate. AZO was chosen due its high piezoelectric coupling coefficient, ease of deposition and excellent bonding with silicon substrate. Doping of ZnO with Al has improved the electrical properties, conductivity and thermal stability. The proposed design operates in transversal mode (d31 mode) which was structured as a parallel plated capacitor using Si/Al/AZO/Al layers. The highlight of this work is the successful design and fabrication of Al/AZO/Al on <100> silicon as the substrate to make the device CMOS compatible for electronic functionality integration. Design and finite element modeling was conducted using COMSOL� software to estimate the resonance frequency. RF Magnetron sputtering was chosen as the deposition method for aluminium and AZO. Material characterization was performed using X-ray diffraction and field emission scanning electron microscopy to evaluate the piezoelectric qualities, surface morphology and the cross section. The fabricated energy harvester generated 1.61 V open circuit output voltage at 7.77 MHz resonance frequency. The experimental results agreed with the simulation results. The measured output voltage is sufficient for low power wireless sensor nodes as an alternative power sources to traditional chemical batteries. � Springer-Verlag 2012.
author2 36537608500
author_facet 36537608500
Md Ralib A.A.
Nordin A.N.
Salleh H.
Othman R.
format Conference paper
author Md Ralib A.A.
Nordin A.N.
Salleh H.
Othman R.
author_sort Md Ralib A.A.
title Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
title_short Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
title_full Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
title_fullStr Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
title_full_unstemmed Fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric MEMS energy harvesters
title_sort fabrication of aluminium doped zinc oxide piezoelectric thin film on a silicon substrate for piezoelectric mems energy harvesters
publishDate 2023
_version_ 1806423432001224704
score 13.214268

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