Excitation by acoustic vibration as an effective tool for improving the characteristics of the solution-processed coatings and thin films

•Major fluid dynamic effects as a result of acoustic vibration created in liquids are discussed.•Application of acoustic vibration for post treatment of thin films is discussed.•Effect of acoustic vibration on stability of thin films is elucidated.•Literature in the area of thin film fabrication emp...

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Bibliographic Details
Published in:Progress in organic coatings 2017-12, Vol.113, p.60-73
Main Author: Eslamian, Morteza
Format: Article
Language:English
Subjects:
Acoustic excitation
Acoustic vibration
Coating effects
Controllability
Fluid dynamics
Fluid flow
Liquid films
Organic coatings
Photovoltaic cells
Pinholes
Protective coatings
Reproducibility
Solar cells
Surface waves
Thin film devices
Thin films
Thin liquid films
Thin solid films
Ultrasonic vibration
Vibration
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Summary:•Major fluid dynamic effects as a result of acoustic vibration created in liquids are discussed.•Application of acoustic vibration for post treatment of thin films is discussed.•Effect of acoustic vibration on stability of thin films is elucidated.•Literature in the area of thin film fabrication employing acoustic vibration is reviewed.•Effect of electric and magnetic fields on thin films is briefly considered. Solution-processed thin films and coatings have received tremendous attention in recent years, as a substitute for vapor-phase grown films, to develop low-cost devices, such as thin film solar cells, displays, sensors, etc. The challenge, however, is to overcome the lack of adequate controllability and reproducibility of solution-processed thin films which inherently contain excessive pinholes and other defects, particularly when processed at low temperatures. In this review, it is substantiated that imposed sound and ultrasound vibrations could result in significant improvements in the nanostructure, uniformity, and functionality of the resulting thin solid films. Using a wealth of information in the fluid dynamics literature, it is demonstrated that the acoustic excitation results in creation of fluid flow, such as streaming, microstreaming, and surface waves, as well as enhanced heat transfer, causing improvement in the quality and characteristics of the thin films prepared by vibration-assisted techniques, even though the vibration tends to destabilize the liquid films. In addition, the pertinent works that have exploited this effect to prepare high performance materials are critically reviewed and the results are discussed and interpreted in the framework of fluid dynamics. A brief review on the effect of imposing other external fields including electric and magnetic fields on the fabrication process and characteristics of the thin films is also provided.
ISSN:0300-9440
1873-331X
DOI:10.1016/j.porgcoat.2017.08.008