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Microfluidics control the ballistic energy of thermocavitation liquid jets for needle-free injections

Loreto Oyarte Gálvez, Arjan Fraters, Herman L. Offerhaus, Michel Versluis, Ian W. Hunter, David Fernández Rivas

2020Journal of Applied Physics31 citationsDOIOpen Access PDF

Abstract

Illuminating a water solution with a focused continuous wave laser produces a strong local heating of the liquid that leads to the nucleation of bubbles, also known as thermocavitation. During the growth of the bubble, the surrounding liquid is expelled from the constraining microfluidic channel through a nozzle, creating a jet. The characteristics of the resulting liquid jet were imaged using ultra-fast imaging techniques. Here, we provide a phenomenological description of the jet shapes and velocities and compare them with a boundary integral numerical model. We define the parameter regime, varying jet speed, taper geometry, and liquid volume for optimal printing, injection, and spray applications. These results are important for the design of energy-efficient needle-free jet injectors based on microfluidic thermocavitation.

Topics & Concepts

MicrofluidicsJet (fluid)MechanicsInjectorNucleationMaterials scienceVolume (thermodynamics)FluidicsCavitationNozzleBoundary value problemFlow control (data)Control volumeOpticsLaserBoundary (topology)Volume of fluid methodBubbleMixing (physics)Fluid dynamicsCapillary actionEnergy (signal processing)Channel (broadcasting)VelocimetryFlow visualizationFlow (mathematics)Computer simulationPhenomenological modelUltrasound and Cavitation PhenomenaFluid Dynamics and Heat TransferElectrohydrodynamics and Fluid Dynamics
Microfluidics control the ballistic energy of thermocavitation liquid jets for needle-free injections | Litcius