Member of
Contributors
Publisher
Florida Atlantic University
Date Issued
2017
EDTF Date Created
2017
Description
Aqueous microdroplets have shown great potential
in various applications such as material synthesis,
chemical reactions, and drug discovery. The
objective of this research is to generate aqueous
microdroplets in water using microfluidic techniques.
Compared to conventional aqueous droplets in an oil
phase, droplets generated from the proposed system
will be more biocompatible and simply manufactured.
To achieve this goal, the research focuses on
understanding fundamental physics behind droplet
generation at various geometries and input conditions.
This understanding can subsequently help us
obtain microdroplets with targeted properties. Several
microdroplet generators made of polydimethylsiloxane
(PDMS) transparent polymer are fabricated
and an aqueous two-phase system (ATPS) made up
of two water-based polymers, polyethylene glycol
(PEG) and dextran (DEX) is used in these generators.
The results successfully demonstrate that the
proposed droplet generators produce aqueous microdroplets
at various sizes at different frequencies.
The controllability and tunability of the properties of
microdroplets will be discussed.
in various applications such as material synthesis,
chemical reactions, and drug discovery. The
objective of this research is to generate aqueous
microdroplets in water using microfluidic techniques.
Compared to conventional aqueous droplets in an oil
phase, droplets generated from the proposed system
will be more biocompatible and simply manufactured.
To achieve this goal, the research focuses on
understanding fundamental physics behind droplet
generation at various geometries and input conditions.
This understanding can subsequently help us
obtain microdroplets with targeted properties. Several
microdroplet generators made of polydimethylsiloxane
(PDMS) transparent polymer are fabricated
and an aqueous two-phase system (ATPS) made up
of two water-based polymers, polyethylene glycol
(PEG) and dextran (DEX) is used in these generators.
The results successfully demonstrate that the
proposed droplet generators produce aqueous microdroplets
at various sizes at different frequencies.
The controllability and tunability of the properties of
microdroplets will be discussed.
Language
Type
Genre
Form
Extent
1 p.
Subject (Topical)
Identifier
FA00005629
Date Backup
2017
Date Created Backup
2017
Date Text
2017
Date Created (EDTF)
2017
Date Issued (EDTF)
2017
Extension
FAU
IID
FA00005629
Organizations
Attributed name: Office of Undergraduate Research and Inquiry
Person Preferred Name
Melgar Jimenez, Sofia
Physical Description
application/pdf
1 p.
Title Plain
Fundamental Physics of All-Aqueous Micro-Droplet Generation Mechanisms
Origin Information
2017
2017
Florida Atlantic University
Boca Raton, Florida
Physical Location
Florida Atlantic University Libraries
Place
Boca Raton, Florida
Sub Location
Digital Library
Title
Fundamental Physics of All-Aqueous Micro-Droplet Generation Mechanisms
Other Title Info
Fundamental Physics of All-Aqueous Micro-Droplet Generation Mechanisms