Abstract
For applications in optical communication, sensing or information projection in automotive lighting, polymer based optical devices are of keen interest. Optical structures such as waveguides and gratings are basic blocks for these devices. We report on a simple, versatile, and yet low-cost fabrication method suited for both binary and multilevel diffractive microstructures as well as multimode optical waveguides in polymers. The fabrication of the diffractive structures, i.e. gratings, with two and multiple levels, is achieved by using a maskless optical lithography system employing a spatial light modulator. With the same system, waveguide cladding structures are realized by stitching of multiple single exposure patterns. For replication of these structures on polymer, e.g. polymethyl methacrylate (PMMA), a lab-made hot embossing machine is used. We then employ UV curable material and doctor blading to realize the waveguide cores. The created diffractive and waveguide structures are characterized in terms of diffraction efficiency and optical propagation loss, respectively, showing good optical quality and performance. With our fabrication system we have demonstrated a diffraction efficiency of 71% for multilevel grating structure and a propagation loss for stitched waveguides of 2.07 dB/cm at a wavelength of 638 nm. These basic elements will be employed to realize entire optical measurement systems for applications in sensing and integrated photonics in the next step.
Highlights
Polymer based optical devices containing microstructures in the sub-micron range are of keen interest for applications in illumination and sensing as well as for optical interconnects [1,2,3,4]
We present a versatile liquid crystal display spatial light modulator (LCD SLM) based method for reliable fabrication of both binary and multilevel microstructures as well as multimode optical waveguides on polymer material, i.e. polymethyl methacrylate (PMMA), by combining maskless lithography and soft replication using hot embossing and doctor blading
The method and optical system presented in this work to create polymer micro- and tentatively nanostructures, i.e. binary and multilevel gratings as well as multimode waveguides, provides flexibility for producing even smaller structures by using higher de-magnification lenses
Summary
Polymer based optical devices containing microstructures in the sub-micron range are of keen interest for applications in illumination and sensing as well as for optical interconnects [1,2,3,4]. A digital micro mirror device (DMD), or a liquid crystal display spatial light modulator (LCD SLM) is used to project micro-patterns and, create microstructures onto photoresist [10,11,12]. The use of an LCD SLM for microstructure pattern projection on the sample, e.g. photoresist, allows the realization of binary level structures and of multilevel structures in comparison to the DMD. Using a laser source for writing microstructures in polymer, e.g. PMMA, a high intensity of incoming light might damage the liquid crystals of the SLM. We present a versatile LCD SLM based method for reliable fabrication of both binary and multilevel microstructures as well as multimode optical waveguides on polymer material, i.e. PMMA, by combining maskless lithography and soft replication using hot embossing and doctor blading
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