Literature DB >> 18232987

Role of the channel geometry on the bubble pinch-off in flow-focusing devices.

Benjamin Dollet1, Wim van Hoeve, Jan-Paul Raven, Philippe Marmottant, Michel Versluis.   

Abstract

The formation of bubbles by flow focusing of a gas and a liquid in a rectangular channel is shown to depend strongly on the channel aspect ratio. Bubble breakup consists in a slow linear 2D collapse of the gas thread, ending in a fast 3D pinch-off. The 2D collapse is predicted to be stable against perturbations of the gas-liquid interface, whereas the 3D pinch-off is unstable, causing bubble polydispersity. During 3D pinch-off, a scaling w_(m) approximately tau(1/3) between the neck width w_(m) and the time tau before breakup indicates that breakup is driven by the inertia of both gas and liquid, not by capillarity.

Year:  2008        PMID: 18232987     DOI: 10.1103/PhysRevLett.100.034504

Source DB:  PubMed          Journal:  Phys Rev Lett        ISSN: 0031-9007            Impact factor:   9.161


  15 in total

1.  Novel preparation techniques for controlling microbubble uniformity: a comparison.

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Journal:  Med Biol Eng Comput       Date:  2009-05-12       Impact factor: 2.602

2.  Experimental Techniques for Bubble Dynamics Analysis in Microchannels: A Review.

Authors:  Mahshid Mohammadi; Kendra V Sharp
Journal:  J Fluids Eng       Date:  2013-03-19       Impact factor: 1.995

3.  Restoring universality to the pinch-off of a bubble.

Authors:  Amir A Pahlavan; Howard A Stone; Gareth H McKinley; Ruben Juanes
Journal:  Proc Natl Acad Sci U S A       Date:  2019-06-17       Impact factor: 11.205

4.  The use of artificial neural networks for optimizing polydispersity index (PDI) in nanoprecipitation process of acetaminophen in microfluidic devices.

Authors:  Mahdi Aghajani; Ahmad Reza Shahverdi; Amir Amani
Journal:  AAPS PharmSciTech       Date:  2012-09-21       Impact factor: 3.246

5.  Production rate and diameter analysis of spherical monodisperse microbubbles from two-dimensional, expanding-nozzle flow-focusing microfluidic devices.

Authors:  Shiying Wang; Ali H Dhanaliwala; Johnny L Chen; John A Hossack
Journal:  Biomicrofluidics       Date:  2013-01-16       Impact factor: 2.800

6.  Lattice Boltzmann simulations capture the multiscale physics of soft flowing crystals.

Authors:  A Montessori; A Tiribocchi; F Bonaccorso; M Lauricella; S Succi
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2020-06-22       Impact factor: 4.226

7.  Dripping and jetting in microfluidic multiphase flows applied to particle and fiber synthesis.

Authors:  J K Nunes; S S H Tsai; J Wan; H A Stone
Journal:  J Phys D Appl Phys       Date:  2013-03-20       Impact factor: 3.207

Review 8.  Scaling up the throughput of microfluidic droplet-based materials synthesis: A review of recent progress and outlook.

Authors:  Jingyu Wu; Sagar Yadavali; Daeyeon Lee; David A Issadore
Journal:  Appl Phys Rev       Date:  2021-09       Impact factor: 19.527

9.  Mixing high-viscosity fluids via acoustically driven bubbles.

Authors:  Sinem Orbay; Adem Ozcelik; James Lata; Murat Kaynak; Mengxi Wu; Tony Jun Huang
Journal:  J Micromech Microeng       Date:  2016-10-25       Impact factor: 1.881

10.  High Efficiency Molecular Delivery with Sequential Low-Energy Sonoporation Bursts.

Authors:  Kang-Ho Song; Alexander C Fan; John T Brlansky; Tammy Trudeau; Arthur Gutierrez-Hartmann; Michael L Calvisi; Mark A Borden
Journal:  Theranostics       Date:  2015-10-18       Impact factor: 11.556
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