Sessile droplet evaporation on patterned surface

Developing and understanding fluidic systems in the area of droplet evaporation requires wide range of studies and such technologies can be useful in microchip manufacturing and ink jet printing with particles. How the droplet evaporate on the different surfaces are what the researches are intereste...

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Main Author: Koh, Han Jie
Other Authors: Fei Duan
Format: Final Year Project
Language:English
Published: 2015
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Online Access:http://hdl.handle.net/10356/63466
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-634662023-03-04T18:39:30Z Sessile droplet evaporation on patterned surface Koh, Han Jie Fei Duan School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering::Fluid mechanics Developing and understanding fluidic systems in the area of droplet evaporation requires wide range of studies and such technologies can be useful in microchip manufacturing and ink jet printing with particles. How the droplet evaporate on the different surfaces are what the researches are interested on. Hence the objective of this project is to analyze the drying pattern and duration of the droplet evaporation on different nanoscale pillar designs which will be relating to printing, coating and material design. Also to measure and record at which volume ratio the mixture will start to change its shape during evaporation and how will the droplet shape change during the evaporation. As far as this project is concerned, all studies done are experimental and duration of the evaporation require without the input of other elements such as heat or external forces. 7 different designs of pillars are used namely triangle, square, diamond, circle, rounded squares and stripes. Height of 100μm, diameter and intervals of 25μm are used throughout all the 7 designs, volume ratios of 0.2 to 1.0, are used for this experiment. The Droplet of various volume and concentrations for evaporation on diverse designs of surfaces and dimensions are widely studied and this report contains a small area of it. Dimensions ranging from 20-180μm pillar height, 5-500μm intervals, volume of less than 1μl and particle sizes of 18-1000μm are used. Cassie and Wenzel models help to shed some light on how they affect and cause the droplets to behave in certain ways or help the evaporation to slow down or speed up compared to others. Understanding from how the surface designs affect the droplet evaporation patterns can also allow better material manufacturing on what properties the material requires and hence allow better development of future materials. Further studies such as particle addition and using of different compound mixtures at different environment can be further done to further improve and broaden the study done from this project. Different surface design can also be explored on top these mentioned study patterns. Bachelor of Engineering (Mechanical Engineering) 2015-05-14T01:42:19Z 2015-05-14T01:42:19Z 2015 2015 Final Year Project (FYP) http://hdl.handle.net/10356/63466 en Nanyang Technological University 111 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Mechanical engineering::Fluid mechanics
spellingShingle DRNTU::Engineering::Mechanical engineering::Fluid mechanics
Koh, Han Jie
Sessile droplet evaporation on patterned surface
description Developing and understanding fluidic systems in the area of droplet evaporation requires wide range of studies and such technologies can be useful in microchip manufacturing and ink jet printing with particles. How the droplet evaporate on the different surfaces are what the researches are interested on. Hence the objective of this project is to analyze the drying pattern and duration of the droplet evaporation on different nanoscale pillar designs which will be relating to printing, coating and material design. Also to measure and record at which volume ratio the mixture will start to change its shape during evaporation and how will the droplet shape change during the evaporation. As far as this project is concerned, all studies done are experimental and duration of the evaporation require without the input of other elements such as heat or external forces. 7 different designs of pillars are used namely triangle, square, diamond, circle, rounded squares and stripes. Height of 100μm, diameter and intervals of 25μm are used throughout all the 7 designs, volume ratios of 0.2 to 1.0, are used for this experiment. The Droplet of various volume and concentrations for evaporation on diverse designs of surfaces and dimensions are widely studied and this report contains a small area of it. Dimensions ranging from 20-180μm pillar height, 5-500μm intervals, volume of less than 1μl and particle sizes of 18-1000μm are used. Cassie and Wenzel models help to shed some light on how they affect and cause the droplets to behave in certain ways or help the evaporation to slow down or speed up compared to others. Understanding from how the surface designs affect the droplet evaporation patterns can also allow better material manufacturing on what properties the material requires and hence allow better development of future materials. Further studies such as particle addition and using of different compound mixtures at different environment can be further done to further improve and broaden the study done from this project. Different surface design can also be explored on top these mentioned study patterns.
author2 Fei Duan
author_facet Fei Duan
Koh, Han Jie
format Final Year Project
author Koh, Han Jie
author_sort Koh, Han Jie
title Sessile droplet evaporation on patterned surface
title_short Sessile droplet evaporation on patterned surface
title_full Sessile droplet evaporation on patterned surface
title_fullStr Sessile droplet evaporation on patterned surface
title_full_unstemmed Sessile droplet evaporation on patterned surface
title_sort sessile droplet evaporation on patterned surface
publishDate 2015
url http://hdl.handle.net/10356/63466
_version_ 1759855296121929728