Droplet-based microfluidics systems have become widely used in recent years thanks to their advantages, varying from the possibility of handling small fluid volumes to directly synthesizing and encapsulating various living forms for biological-related applications. The effectiveness of such systems mainly depends on the ability to control some of these systems' parameters, such as produced droplet size and formation time, which represents a challenging task. This work reports an experimental study on tuning droplet size and generation time in a flow-focusing geometry fabricated with stereolithography 3D printing by exploring the interplay of phase and geometrical parameters. We produced droplets at different low flow rates of continuous and dispersed phases to assess the effect of each of these phases on the droplets' size and formation time. We observed that smaller droplets were produced for high viscosity oil and water phase, along with high flow rates. In addition, changing the microfluidics channels' width, and morphology of the orifice has shown a similar effect on droplet size, as shown in the case of high-viscosity solutions. The variation of the bifurcation angle shows a noticeable variation in terms of the achieved droplet size and formation time. We further investigated the impact of modifying the width ratio of the continuous and dispersed phases on droplet formation.

3D printing in micro fluidics: experimental optimization of droplet size and generation time through fl ow focusing, phase, and geometry variation

Adam Britel
;
Giulia Tomagra;Pietro Aprà;Veronica Varzi;Sofia Sturari;Nour-Hanne Amine;Paolo Olivero;Federico Picollo
2024-01-01

Abstract

Droplet-based microfluidics systems have become widely used in recent years thanks to their advantages, varying from the possibility of handling small fluid volumes to directly synthesizing and encapsulating various living forms for biological-related applications. The effectiveness of such systems mainly depends on the ability to control some of these systems' parameters, such as produced droplet size and formation time, which represents a challenging task. This work reports an experimental study on tuning droplet size and generation time in a flow-focusing geometry fabricated with stereolithography 3D printing by exploring the interplay of phase and geometrical parameters. We produced droplets at different low flow rates of continuous and dispersed phases to assess the effect of each of these phases on the droplets' size and formation time. We observed that smaller droplets were produced for high viscosity oil and water phase, along with high flow rates. In addition, changing the microfluidics channels' width, and morphology of the orifice has shown a similar effect on droplet size, as shown in the case of high-viscosity solutions. The variation of the bifurcation angle shows a noticeable variation in terms of the achieved droplet size and formation time. We further investigated the impact of modifying the width ratio of the continuous and dispersed phases on droplet formation.
2024
Inglese
Esperti anonimi
14
7770
7778
9
no
   OLIVERO P. - Prog. UE n. 956387 - H2020-MSCA-ITN-2020 - "LasIonDef - Training on laser fabrication and ion implantation of defects as quantum emitters"
   LasIonDef
   EUROPEAN COMMISSION
   H2020
   956387

   OLIVERO P. - FISR 2019 - "Intelligent fabrication of QUANTum devices in DIAmond by Laser and Ion Irradiation"
   QuantDia
   MINISTERO DELL'ISTRUZIONE, DELL'UNIVERSITA' E DELLA RICERCA
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Adam Britel, Giulia Tomagra, Pietro Aprà, Veronica Varzi, Sofia Sturari, Nour-Hanne Amine, Paolo Olivero, Federico Picollo
info:eu-repo/semantics/article
open
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2318/1960204
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