Light induced fluidic waveguide coupling

Volker Zagolla; Eric Tremblay; Christophe Moser

doi:10.1364/OE.20.00A924

Optics Express
Vol. 20,
Issue S6,
pp. A924-A931
(2012)
•https://doi.org/10.1364/OE.20.00A924

Light induced fluidic waveguide coupling

Volker Zagolla, Eric Tremblay, and Christophe Moser

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Volker Zagolla, Eric Tremblay, and Christophe Moser, "Light induced fluidic waveguide coupling," Opt. Express 20, A924-A931 (2012)

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Abstract

We report on the development of an opto-fluidic waveguide coupling mechanism for planar solar concentration. This mechanism is self-adaptive and light-responsive to efficiently maintain waveguide coupling and concentration independent of incoming light’s direction. Vapor bubbles are generated inside a planar, liquid waveguide using infrared light on an infrared absorbing glass. Visible light focused onto the bubble is then reflected by total internal reflection (TIR) at the liquid-gas interface and coupled into the waveguide. Vapor bubbles inside the liquid are trapped by a thermal effect and are shown to self-track the location of the infrared focus. Experimentally we show an optical to optical waveguide coupling efficiency of 40% using laser light through a single commercial lens. Optical simulations indicate that coupling efficiency > 90% is possible with custom optics.

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Fig. 1 Principle of the opto-fluidic concentrator. (a) Light is focused to a ring inside the waveguide. (b) Once a bubble is generated, light is reflected from the bubble by TIR and coupled into the waveguide.

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Fig. 2 Theoretical target space: a scale invariant volume space that defines all parameters dependent on the coupling efficiency (a) Efficiency > 50%, (b) Efficiency > 90%. The inset in (a) shows our demonstration system while the inset in (b) shows a solution for 100% coupling efficiency (neglecting scattering and Fresnel reflections).

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Fig. 3 Simulation results on the coupling efficiency in an off-axis illumination configuration as a function of the light’s incident angle.

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Fig. 4 Schematic of the setup. Two lasers are co-propagating and focused on the IR absorbing glass.

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Fig. 5 (a) Photograph of the experimental fluidic chamber. The BG39 is clearly visible (blue glass). (b) Photograph showing the bubble and the focus ring for illustrating purposes.

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Fig. 6 (a) Experiment: Bubble size for specific power levels, as a function of time for an existing bubble. (b) Experiment vs. Simulation: Light reaching Detector vs. Bubble size.

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Fig. 7 Illustration of the tracking of a vapor bubble ( Media 1).

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Abstract

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