Browsing by Subject "GRIN"
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Item Generation of Gradient Index Optics with Subwavelength Metamaterials(2019-07) Borowiak, AndrewA GRIN optic is a useful device for modern optics but is not frequently used outside of niche applications due to the difficulty of fabricating any arbitrary gradient index. One potential solution to this fabrication problem is to use subwavelength metamaterials generated using lithography. A process was developed to generate a subwavelength waveguide which leverages effective medium theory to behave like a GRIN optic. This process was tested by generating waveguides as well as mode converters for converting from gaussian beams to supergaussian beams. The results from these experiments show that this technique could produce mode converters with average Strehl ratios of 0.997 and an average transmission of 94.8% on the scale of tens of microns; however, it was found that these designs are not viable for modern lithographic fabrication techniques. There is much to explore still with this topic such as the lower size limits of these designs or whether modern lithography could make a mode converter with this structure.Item Passive coherent beam combining by gain effects in fiber lasers and spatial beam control in gradient refractive index media(2018-10) Kunkel, WilliamThis thesis addresses two topics in coherent beam combining. First, a fiber laser with two parallel gain elements is considered, where the phase difference between beams is passively adjusted by the difference in gain, via Kramers-Kronig phase. This addresses an important aspect of beam combining, whereby phase agreement is attained between constituent beams. The second part of this thesis is devoted to beam shaping with custom gradient-index optics. Control over the spatial characteristics of laser beams is essential for efficient combining, as overlapped beams must interfere constructively across their entire transverse profile. An experiment is conducted to isolate and measure the Kramers-Kronig phase of the fiber laser mode. Measurements support a nonlinear model of passive phasing in the resonator, showing that the gain self-adjusts in response to externally applied phase errors between the arms of the resonator. The effect can be harnessed to achieve efficient beam combining without external feedback to the laser array. We also describe a numerical design method to create spatially-varying refractive index functions that accomplish arbitrary beam transformations in two and three dimensions. The refractive index designs compensate the effects of diffraction, overcoming the limitations of traditional optics such as aspheric lenses and diffractive optics. Example designs, such as a Gaussian-to-supergaussian mode converter and an array beam combiner, are shown. A device fabricated by femtosecond laser writing is tested experimentally.