We have proposed, designed, manufactured and tested low loss dielectric micro-lenses for infrared (IR) radiation based on a dielectric metamaterial layer. This metamaterial layer was created by patterning a dielectric surface and etching to sub-micron depths. For a proof-of-concept lens demonstration, we have chosen a fine patterned array of nano-pillars with variable diameters. Gradient index (GRIN) properties were achieved by engineering the nano-pattern characteristics across the lens, so that the effective optical density of the dielectric metamaterial layer peaks around the lens center, and gradually drops at the lens periphery. A set of lens designs with reduced reflection and tailorable phase gradients have been developed and tested, demonstrating focal distances of a few hundred microns, beam area contraction ratio up to three, and insertion losses as low as 11%.
Degenerate four-wave mixing (DFWM) spectroscopy is modified to exploit femtosecond pulses, phase-sensitive-detection, frequency (wavelength) agility, two-color (nearly degenerate multiwave mixing) radiation, and
improved signal-to-noise capabilities that can be realized through a combination of new solid state lasers,
nonlinear optical components, and novel design concepts. The resulting time-resolved nonlinear optical
techniques permit “instantaneous” optical nonlinearities, such as two-photon absorption cross sections, to be
accurately measured over the spectral range from 450 to 2500 nm (and with significantly greater effort from
225 to 5000 nm). The power of the new techniques is illustrated by their application to the definition of Hg
two-photon resonances of C60 and C70 as well as to the characterization of optical nonlinearities in two linear
chromophores of putative utility for sensor protection and electrooptic modulation. Explicitly, these
measurements provide accurate determination of both transition energies and transition moments (matrix
elements connecting the two photon levels). Results are compared to those previously reported in the literature
illustrating the advantages and problems associated with particular measurement techniques. All of the molecules
studied are found to exhibit two-photon absorption coefficients comparable to that of GaAs, the most studied
putative sensor protection material (based on utilization of electronic optical nonlinearity). Femtosecond pulse
techniques are shown, in all cases, to be necessary to avoid complications arising from excited-state absorption
and relaxation phenomena. The importance of phase-sensitive detection in identifying complications from
overlapping transitions is illustrated.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.