3D Nano-Printing in Integrated Optics: From Laboratory Experiments to Industrial Production

  1. Institute of Microstructure Technology, Karlsruhe Institute of Technology (KIT)

christian.koos@kit.edu

Multi-photon lithography has become a powerful tool for additive 3D fabrication on the micro- and nano-scale. This talk will give an overview on our progress in leveraging lithographic 3D nano-printing as a tool for integrated optics. We exploit the technique for fabrication of 3D freeform single-mode waveguides, so-called photonic wire bonds, that can efficiently connect optical chips within a chip-scale package, without the need for high-precision active alignment steps. Photonic wire bonding builds the base of highly flexible photonic multi-chip modules that combine different optical integration platforms in a hybrid approach. 3D nano-printing also allows fabrication of freeform micro-optical elements with highest precision directly on the facets of integrated optical devices. Such facet-attached elements allow for beam-shaping, low-loss coupling with high alignment tolerance, or wafer-level probing of optical devices. While the viability of these concepts has been demonstrated in laboratory experiments in a first step, they are now made available to industrial applications through dedicated production tools along with robust and scalable fabrication processes.

Manuscript not yet submitted. The submission phase is currently closed.
@inproceedings{dgao121-h7, title = {3D Nano-Printing in Integrated Optics: From Laboratory Experiments to Industrial Production}, author = {Christian Koos}, booktitle = {DGaO-Proceedings, 121. Jahrestagung}, year = {2020}, publisher = {Deutsche Gesellschaft für angewandte Optik e.V.}, issn = {1614-8436}, note = {Talk H7} }
121. Annual Conference of the DGaO · Bremen · 2020