Co-planar light-actuated optoelectrowetting microfluidic device for droplet manipulation

Abstract: We report on a co-planar light-actuated digital microfluidics device that features a metal mesh grid integrated on the device surface to allow droplets to be exposed from above. We discuss a theoretical circuit model for our co-planar optoelectrowetting (OEW) design that allows for the optimization of droplet actuation while maintaining reliable droplet movement. Basic droplet manipulations such as merging and parallel actuation of droplets are achieved at speeds of up to 4.5 cm∕s. The co-planar OEW device des… Show more

“…Overall, the optical nanofiber is an effective tool for precise optical manipulation of Janus particles and their applications as micro- or nanoscale actuators or transporters. We envisage further development of plasmonic 55 and waveguide-based technologies with Janus particles, in particular contributing to the prospective “rail”-style microfluidic designs 56 , 57 .…”

Evanescent field trapping and propulsion of Janus particles along optical nanofibers

“…Overall, the optical nanofiber is an effective tool for precise optical manipulation of Janus particles and their applications as micro- or nanoscale actuators or transporters. We envisage further development of plasmonic 55 and waveguide-based technologies with Janus particles, in particular contributing to the prospective “rail”-style microfluidic designs 56 , 57 .…”

Evanescent field trapping and propulsion of Janus particles along optical nanofibers

“…[284] As it was mentioned before, the different stimulus-responsive surfaces with tunable wetting offer viable alternatives for flow actuation at the sub-mm scale and for droplet manipulation (merging, transportation), as well. Among all possible stimuli, electrowetting applications are superior and the most widespread, thanks to the excellent miniaturizeability and fast response [296][297][298][299]. Moreover, applying photoconductor & semiconductor materials, light-controlled optoelectrowetting microfluidic devices are also implementable.…”

“…Moreover, applying photoconductor & semiconductor materials, light-controlled optoelectrowetting microfluidic devices are also implementable. Recently, Loo et al prepared such devices, capable of quick droplet manipulation with light intensity-and frequency-dependent operation speed [296]. An another interesting concept utilizes azobenzene photoswitch-modified liquid crystal polymer surfaces to create propagating surface waves, that are capable of driving liquid flow.…”

Fundamentals and utilization of solid/ liquid phase boundary interactions on functional surfaces

“…7,8 According to various forms of external energy input, the first category above can be further divided into the following strategies: (1) Light energy: the solid surface is first modified by chemical molecules that respond to the light intensity, and subsequently a beam of asymmetrical light is illuminated on the modified surface to generate a surface energy gradient, which drives the droplet forward. In a word, this strategy is primarily based on the radiation-induced pressure, 9 optoelectronic wetting, 10 and photoinduced capillary force, 11 which can generate a limited traction and thus struggles to overcome the pinned resistance of the droplet. 12 (2) Thermal energy: as discovered by Leidenfrost, a droplet that is placed on hightemperature surfaces can be held up by its own vapor layer and move along the ratcheting structure, while the high-temperature surface tends to cause the evaporation loss of liquid droplets.…”

Surface Charge Density Gradient Printing To Drive Droplet Transport: A Numerical Study