Analysis of additive manufactured polymer optical waveguides: measurement and simulation of their waviness

Backhaus C, Hoffmann GA, Reitberger T, Eiche Y, Overmeyer L, Franke J, Lindlein N (2020)

Publication Language: English

Publication Type: Conference contribution, Conference Contribution

Publication year: 2020

Publisher: SPIE

Book Volume: 11283

Pages Range: 193 -- 202

Conference Proceedings Title: Integrated Optics: Devices, Materials, and Technologies XXIV

Event location: San Francisco, California, United States

DOI: 10.1117/12.2543202

Abstract

This paper analyzes an approach for additively manufacturing polymer optical waveguides. The production process includes flexographic printing of conditioning lines (5 μm height) on a substrate, which are used as guiding barriers in the subsequent printing of the optical core. The core is additively printed (up to 50 μm in height) with an aerosol jet printer, filling the gap between the conditioning lines. The conditioning lines do not only enhance the contact angle of the polymer, which results in a higher cross section of the waveguides, but also improve the straight edges of the printed waveguides. We show that the quality of the conditioning lines is directly correlated to the waviness of the waveguides. Consequently, the analyses of the waviness of the conditioning lines classifies the quality of the fabricated waveguides. However, the waviness of the waveguides can also be considered in optical simulations. In this paper we show how we derive a waveguide model with waviness by fitting a single sine function onto the topological data of the conditioning lines. With this model a variation of the waviness can easily be simulated and goals for fabrication can be set. With the simulations it is possible to verify that the measured waviness (period of 559.5 μm and an amplitude of 4.99 μm) does not affect the optical quality of the waveguides.

Authors with CRIS profile

Carsten Backhaus Lehrstuhl für Experimentalphysik (Optik) Thomas Reitberger Lehrstuhl für Fertigungsautomatisierung und Produktionssystematik Yannic Eiche Lehrstuhl für Fertigungsautomatisierung und Produktionssystematik Jörg Franke Lehrstuhl für Fertigungsautomatisierung und Produktionssystematik Norbert Lindlein Naturwissenschaftliche Fakultät

Related research project(s)

Modellbildung und Simulation optischer Komponenten auf opto-mechatronischen Baugruppen zur Abbildung charakteristischer Kenngrößen (TP 6) May 1, 2018 - April 30, 2021

Involved external institutions

Gottfried Wilhelm Leibniz Universität Hannover

Germany (DE)

How to cite

APA:

Backhaus, C., Hoffmann, G.-A., Reitberger, T., Eiche, Y., Overmeyer, L., Franke, J., & Lindlein, N. (2020). Analysis of additive manufactured polymer optical waveguides: measurement and simulation of their waviness. In García-Blanco SM, Cheben P (Eds.), Integrated Optics: Devices, Materials, and Technologies XXIV (pp. 193 -- 202). San Francisco, California, United States, US: SPIE.

MLA:

Backhaus, Carsten, et al. "Analysis of additive manufactured polymer optical waveguides: measurement and simulation of their waviness." Proceedings of the SPIE OPTO, San Francisco, California, United States Ed. García-Blanco SM, Cheben P, SPIE, 2020. 193 -- 202.

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