Login (DCU Staff Only)
Login (DCU Staff Only)

DORAS | DCU Research Repository

Explore open access research and scholarly works from DCU

Advanced Search

Microfluidic device prototyping via laser processing of glass and polymer materials

Ben Azouz, Aymen (2014) Microfluidic device prototyping via laser processing of glass and polymer materials. PhD thesis, Dublin City University.

Abstract
In this thesis, three different processes for the fabrication of microchannels in three different base materials were experimentally and numerically modelled in detail in order to understand the effects of processing conditions on process fabrication capabilities. CO2 and Nd:YAG laser processing systems as well as a xurography technique were employed in this work for the development of microfluidic channels. The effects of CO2 laser processing on the process of directly writing microchannels on surface of four different types of glass: soda lime, fused silica, borosilicate and quartz were studied. Mathematical models were developed to relate the process input parameters to the dimensions of the microchannels. The effect of laser processing on the optical transmission capabilities of the glass was also assessed. A novel method, using Nd:YAG laser system, was employed for the fabrication of internal microchannels inside polymeric materials. Microchannels up to three millimetres long were successfully created inside a polycarbonate within a single laser processing step. Mathematical models were developed to express the relationship between laser processing input parameters and the width of these internal microchannels. The Nd:YAG processing parameters for laser welding of polycarbonate sheets were also determined. A new rapid low-cost prototyping method for the fabrication of multilayer microfluidic devices from cyclic olefin copolymer (COC) films was developed. CO2 laser cutting and xurography techniques were employed for the fabrication of the microfluidic features, followed by multilayer lamination via cyclohexane vapour exposure. Process parameters were optimised including solvent exposure time. Functional UV-transparent microfluidic mixing devices were demonstrated which included internally bound polymer monolithic columns within the microfluidic channels. There is a growing interest to use technologies which are in this thesis, the three different developed processes for the fabrication of microchannels in three different base materials provides the basis for achieving higher dimensional accuracies and novel designs within lab-on-a-chip microfluidic sensing devices.
Metadata
Item Type:Thesis (PhD)
Date of Award:March 2014
Refereed:No
Supervisor(s):Brabazon, Dermot and Vázquez, Mercedes
Subjects:Engineering > Materials
Biological Sciences > Microfluidics
Engineering > Mechanical engineering
Engineering > Production engineering
Physical Sciences > Lasers
Physical Sciences > Photonics
DCU Faculties and Centres:Research Institutes and Centres > Irish Separation Science Cluster (ISSC)
Research Institutes and Centres > National Centre for Plasma Science and Technology (NCPST)
Research Institutes and Centres > Advanced Processing Technology Research Centre (APTRC)
DCU Faculties and Schools > Faculty of Engineering and Computing > School of Mechanical and Manufacturing Engineering
Research Institutes and Centres > National Centre for Sensor Research (NCSR)
Use License:This item is licensed under a Creative Commons Attribution-NonCommercial-No Derivative Works 3.0 License. View License
Funders:Science Foundation Ireland
ID Code:19697
Deposited On:01 Apr 2014 10:42 by Dermot Brabazon . Last Modified 04 Dec 2019 13:44
Documents

Full text available as:

[thumbnail of Aymen_BenAzouz_PhD_Thesis_2013.pdf]
Preview
PDF - Requires a PDF viewer such as GSview, Xpdf or Adobe Acrobat Reader
Creative Commons: Attribution-Noncommercial-No Derivative Works 3.0
17MB
Downloads

Downloads

Downloads per month over past year

Archive Staff Only: edit this record