Structuring light using solgel hybrid 3D-printed optics prepared by two-photon polymerization.

Three-dimensional direct laser writing based on a two-photon polymerization process of hybrid organic-inorganic material was used to print micrometer-scale refractive phase elements that were designed to manipulate incoming Gaussian beams into line and square intensity-flattened profiles. Here we present new results of shaping light beams, enabled by tailoring a two-photon absorption process for printing hybrid material structures based on a fast solgel process. The optical design and calculations of the optical elements are described, along with characterization of their performance in manipulating incoming light beams.

Variable optical attenuator and dynamic mode group equalizer for few mode fibers.

Variable optical attenuation (VOA) for three-mode fiber is experimentally presented, utilizing an amplitude spatial light modulator (SLM), achieving up to -28dB uniform attenuation for all modes. Using the ability to spatially vary the attenuation distribution with the SLM, we also achieve up to 10dB differential attenuation between the fiber's two supported mode group (LP₀₁ and LP₁₁). The spatially selective attenuation serves as the basis of a dynamic mode-group equalizer (DME), potentially gain-balancing mode dependent optical amplification.