Chalcogenide glasses for advanced photonic and photovoltaic applications

Date
2015
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University of Delaware
Abstract
Chalcogenide glasses, namely the amorphous compounds containing sulfur, selenium, and/or tellurium, have emerged as a promising material candidate for integrated photonics given their wide infrared transparency window, low processing temperature, almost infinite capacity for composition alloying, as well as high linear and nonlinear indices. Here we present the fabrication and characterization of chalcogenide glass based photonic devices integrated on silicon, solar cells as well as on flexible polymer substrates for advanced photonic and photovoltaic applications. In this work we developed a low-cost method to deposit glassy films while retaining glass stoichiometry and high optical quality for photonic and photovoltaic applications. As2Se3 amorphous thin films were prepared by standard spin-coating techniques from their organic amine solution with glass loading concentrations as high as 0.5 g/ml. The prepared films were stabilized at elevated temperatures. Physiochemical properties of the spin-coated films were studied and compared with thermal evaporated As2Se3 thin film. ChG photonic devices including gratings, waveguides and resonators, can be fabricated using nanoimprint. This technique offers a convenient, high-throughput, and low-cost approach for patterning of sub-micron glass structures. We rationalized the processing design and modified the material composition to successfully pattern the glass structures. Finite element analysis aligned well with the experimental imprinting results. The imprinted resonators exhibited an ultra-high quality factor of 4 × 10^5 near 1550 nm wavelengths, which represents the highest value reported in chalcogenide glass microring resonators. We further demonstrated that nanoimprint is a versatile technique for the fabrication of photonic structures on flexible polymer substrates. Waveguides, microring resonators, and diffraction gratings fabricated from solution processed ChG films can be monolithically integrated with organic polymer substrates to create mechanically flexible, high-index-contrast photonic devices. The resonators exhibit a high quality factor (Q-factor) of 80 000 near 1550 nm wavelength. Free-standing, flexible ChG gratings whose diffraction properties can be readily tailored by conformal integration on nonplanar surfaces are also demonstrated. Lastly, chalcogenide glasses can be used for the solar cell light trapping applications. We theoretically analyzed and numerically designed novel light-trapping grating structures which provides light trapping enhancement well exceeding the conventional Lambertian limit, by breaking the structural symmetry in conventional grating designs to maximize the guided mode contribution to optical absorption. The light-trapping enhancement in Si solar cells was numerically studied by optimizing the grating parameters. The results showed that the optimized 1-D gratings lead to 63% increase in optical path length, which represents 44% relative improvement compared to the path length enhancement factor using conventional light-trapping structures. I integrated the gratings with thin c-Si solar cells and characterized the solar cells performance. The enhanced solar cell efficiency from 12.2% to 13% after the integration of gratings and backside reflector proves the effect of the light-trapping.
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