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Design and two-photon direct laser writing of low-loss waveguides, tapers and S-bends

Tigran Baghdasaryan, Koen Vanmol, Hugo Thienpont, Francis Berghmans, Thomas Geernaert, Jürgen Van Erps

2021Journal of Physics Photonics36 citationsDOIOpen Access PDF

Abstract

Abstract Despite the rapid developments in the field of two-photon polymerization-based direct laser writing, limited attention has been paid to the efficient design of optical waveguide-based building blocks. To fill that gap, we have numerically investigated air-clad waveguides, tapers, and S-bends, with the aim to minimize insertion losses, whilst reducing the device sizes. We have first demonstrated waveguides with square and circular cross-sections that are mode-matched with single-mode optical fibers featuring insertion losses below −0.6 dB and −1.5 dB around 1550 nm for lengths of respectively 0.2 mm and 1 mm. We have also identified parabolic tapers that allow for adiabatic transition between a wide range of input and output waveguide sizes. These shapes allow, for example, tapering down from 15 µ m to 2 µ m diameter waveguides over a length as short as 43.2 µ m. We have fabricated a series of such components and confirmed their nearly lossless performance with insertion loss measurements. Finally, we have designed and optimized S-bends with Bezier curve shapes. As a proof-of-principle demonstration, we have fabricated a 160 µ m long S-bend that offsets the waveguide axis by 50 µ m. The insertion loss of the resulting 400 µ m long component, which also included two parabolic tapers, was less than −1.7 dB. Apart from providing design rules and ready-to-use recipes for fabricating low-loss 3D-printed waveguide-based building blocks, we project that our work will spark the development of a series of efficient photonic devices that rely on these components and that can be exploited in diverse application fields.

Topics & Concepts

Insertion lossTaperingWaveguideMaterials scienceOpticsLaserAdiabatic processSingle-mode optical fiberOptoelectronicsPhysicsComputer scienceThermodynamicsComputer graphics (images)Nonlinear Optical Materials StudiesPhotonic and Optical DevicesAdvanced Fiber Laser Technologies