Multipoint measurements in optically dense media by using two-photon excited fluorescence and a fiber-optic star coupler

Optical multiplexing with an N × N fiber optic star coupler (with N=3, 4, or 8) and two-photon excited fluorescence is used to achieve multipoint measurements in highly absorbing environments. Differentiation of fluorescence signals from various sampling points was attained by implementing the time-of-flight characteristics of fiber light-guides. Because the transit time of a light pulse through a fiber optic depends largely on the length of the fiber waveguide, fibers of various lengths permit discrimination of the different sampling points in time. With the help of nanosecond time-resolved detection, it was possible to determine the concentration information at several sensing locations simultaneously. Calibration graphs for 2-(1-napththyl)-5-phenyloxazole were linear for all sizes of star coupler, with submillimolar detection limits. Nonlinear excitation of dopants inside the fiber core resulted in an emission signal that depended quadratically on laser power and, as such, was used as an “internal” sensor to correct for power-squared source fluctuations.