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Q: Fachverband Quantenoptik und Photonik

Q 17: Photonics and Biophotonics I

Q 17.2: Vortrag

Dienstag, 3. März 2026, 11:15–11:30, P 3

Active Electrically Switchable Polymer Metasurfaces for Microscope Imaging Functionalities — •Dominik Ludescher¹, Leander Siegle¹, Robert Horvat¹, Jonas Herbig¹, Pavel Ruchka¹, Junqi Lu², Marcos A. Dahlem², Sabine Ludwigs², Mario Hentschel¹, and Harald Giessen¹ — ¹4th Physics Institute and Research Center SCoPE, University of Stuttgart, Germany — ²IPOC - Functional Polymers, Institute of Polymer Chemistry, University of Stuttgart, Germany

Integrating dynamic functionalities into 3D-printed optical components has remained a major challenge, leaving printed optics limited to static behavior. Electrically tunable materials such as the conducting polymer PEDOT:PSS offer a promising route toward adaptive, and compact optoelectronic systems. A key bottleneck has been the high-resolution patterning of PEDOT:PSS. However, we recently introduced two direct nanofabrication strategies that overcome these limitations: electron-beam-induced solubility modulation, and laser-based patterning using the same systems employed for two-photon polymerization of optical resins. The latter method enables true nanoscale patterning and is fully compatible with 3D-printed micro-optics. Using these techniques, we present a versatile integration scheme in which tunable PEDOT:PSS structures are positioned either beneath or atop static 3D-printed elements. This hybrid platform enables voltage-controlled transitions between dark-field and bright-field operation at CMOS-compatible voltages from -2 V to +2 V. The approach establishes a robust foundation for future reconfigurable photonic components.

Keywords: Electrically Switchable DF / BF Microscopy; Conducting Polymers; 3D-Printed Microoptics; Microscope Imaging Techniques