Controllable direction of liquid jets generated by thermocavitation within a droplet

A high-velocity fluid stream ejected from an orifice or nozzle is a common mechanism to produce liquid jets in inkjet printers or to produce sprays among other applications. In the present research, we show the generation of liquid jets of controllable direction produced within a sessile water dropl...

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Published in:Applied optics (2004) 2017-09, Vol.56 (25), p.7167
Main Authors: Padilla-Martinez, J P, Ramirez-San-Juan, J C, Berrospe-Rodriguez, C, Korneev, N, Aguilar, G, Zaca-Moran, P, Ramos-Garcia, R
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cited_by cdi_FETCH-LOGICAL-c329t-d12b2c1fa037e73e2ed3fa6c922bcea7a9cf4de58feb2091bbfdcfd86ed27d4b3
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container_end_page
container_issue 25
container_start_page 7167
container_title Applied optics (2004)
container_volume 56
creator Padilla-Martinez, J P
Ramirez-San-Juan, J C
Berrospe-Rodriguez, C
Korneev, N
Aguilar, G
Zaca-Moran, P
Ramos-Garcia, R
description A high-velocity fluid stream ejected from an orifice or nozzle is a common mechanism to produce liquid jets in inkjet printers or to produce sprays among other applications. In the present research, we show the generation of liquid jets of controllable direction produced within a sessile water droplet by thermocavitation. The jets are driven by an acoustic shock wave emitted by the collapse of a hemispherical vapor bubble at the liquid-solid/substrate interface. The generated shock wave is reflected at the liquid-air interface due to acoustic impedance mismatch generating multiple reflections inside the droplet. During each reflection, a force is exerted on the interface driving the jets. Depending on the position of the generation of the bubble within the droplet, the mechanical energy of the shock wave is focused on different regions at the liquid-air interface, ejecting cylindrical liquid jets at different angles. The ejected jet angle dependence is explained by a simple ray tracing model of the propagation of the acoustic shock wave inside the droplet.
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title Controllable direction of liquid jets generated by thermocavitation within a droplet
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