Confined Flow of Concentrated Emulsions in Microfluidic System

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Abstract/Contents

Abstract: Data Collected by Ya Gai from 2015 to 2018 for the following projects: 1) Optofluidic ultrahigh-throughput detection of fluorescent drops 2) Confinement and viscosity ratio effect on droplet break-up in a concentrated emulsion flowing through a narrow constriction 3) Spatiotemporal periodicity of dislocation dynamics in a two-dimensional microfluidic crystal flowing in a tapered channel 4) Internal flow in droplets within a concentrated emulsion flowing in a microchannel 5) Amphiphilic nanoparticles suppress droplet break-up in a concentrated emulsion flowing through a narrow constriction 6) Strategic obstacle placement reduces drop breakup probability in emulsion flow

Type of resource	software, multimedia
Date created	June 2015 - August 2018

Subject	Stanford
Subject	Mechanical Engineering
Subject	many-body system
Subject	order
Subject	microfluidic crystal
Subject	dislocation dynamics
Subject	plasticity
Subject	Interfacial tension
Subject	Viscous stresses
Subject	Microfluidics
Subject	Proteins
Subject	Nanoparticles
Subject	Microchannel
Subject	Viscoelasticity
Subject	Micro-reactor
Subject	Emulsions
Subject	Thermodynamic states and processes
Genre	Dataset

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Stanford Tang Lab

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