Title :
Electrically driven motion of micro-fluids in air-silica microstructure fiber: application to tunable filter/attenuator
Author :
Kerbage, C. ; Windeler, Robert S. ; Eggleton, Benjamin J. ; Mach, P. ; Dolinski, M. ; Rogers, John A.
Author_Institution :
Dept. Opt. Fiber Solutions, Lucent Technol., Murray Hill, NJ, USA
Abstract :
In conclusion, we demonstrate that positioning of fluids along micro-capillary channels inside the fiber enables the manipulation of light at narrow or large bandwidths. This approach uses low voltages, and can be applied to different fluids. In addition, it has the potential for changing the modal properties of light in fibers in a way that cannot be achieved in other conventional fibers. The motion (magnitude and direction) of the fluid is controlled the amount of pressure or heat delivered by capillary heaters.
Keywords :
micro-optics; microfluidics; optical fibre filters; optical fibre losses; optical fibres; air-silica microstructure fiber; capillary heaters; electrically driven motion; fiber light modal properties changing; fluids positioning; heat; large bandwidths; light manipulation; micro-capillary channels; micro-fluids; modal properties; narrow bandwidths; pressure; tunable filter/attenuator; Filters; Microstructure; Optical attenuators; Optical fiber devices; Optical fibers; Optical pumping; Optical sensors; Optical waveguides; Photonic crystal fibers; Tunable circuits and devices;
Conference_Titel :
Optical Fiber Communication Conference and Exhibit, 2002. OFC 2002
Print_ISBN :
1-55752-701-6
DOI :
10.1109/OFC.2002.1036487
