Large‐Scale Bottom‐Up Fabricated 3D Nonlinear Photonic Crystals

Viola Valentina Vogler‐Neuling; Ülle‐Linda Talts; Rebecca Ferraro; Helena Weigand; Giovanni Finco; Joel Winiger; Peter Benedek; Justine Kusch; Artemios Karvounis; Vanessa Wood; Jürg Leuthold; Rachel Grange

doi:10.1002/adpr.202400058

Advanced Photonics Research (Dec 2024)

Large‐Scale Bottom‐Up Fabricated 3D Nonlinear Photonic Crystals

Viola Valentina Vogler‐Neuling,
Ülle‐Linda Talts,
Rebecca Ferraro,
Helena Weigand,
Giovanni Finco,
Joel Winiger,
Peter Benedek,
Justine Kusch,
Artemios Karvounis,
Vanessa Wood,
Jürg Leuthold,
Rachel Grange

Affiliations

Viola Valentina Vogler‐Neuling: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Ülle‐Linda Talts: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Rebecca Ferraro: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Helena Weigand: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Giovanni Finco: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Joel Winiger: Department of Information Technology and Electrical Engineering Institute for Electromagnetic Fields ETH Zurich ETZ K 81 Gloriastrasse 35 Zurich CH‐8092 Switzerland
Peter Benedek: Department of Information Technology and Electrical Engineering Institute for Electronics ETH Zurich ETZ H 96 Gloriastrasse 35 Zurich CH‐8092 Switzerland
Justine Kusch: ETH Zurich ScopeM HPM C 52.1 Otto‐Stern‐Weg 3 Zurich CH‐8093 Switzerland
Artemios Karvounis: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland
Vanessa Wood: Department of Information Technology and Electrical Engineering Institute for Electronics ETH Zurich ETZ H 96 Gloriastrasse 35 Zurich CH‐8092 Switzerland
Jürg Leuthold: Department of Information Technology and Electrical Engineering Institute for Electromagnetic Fields ETH Zurich ETZ K 81 Gloriastrasse 35 Zurich CH‐8092 Switzerland
Rachel Grange: Department of Physics, Optical Nanomaterial Group Institute for Quantum Electronics ETH Zurich Auguste‐Piccard‐Hof 1 Zurich CH‐8093 Switzerland

DOI: https://doi.org/10.1002/adpr.202400058
Journal volume & issue: Vol. 5, no. 12
pp. n/a – n/a

Abstract

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Nonlinear optical effects are used to generate coherent light at wavelengths difficult to reach with lasers. Materials periodically poled or nanostructured in the nonlinear susceptibility in three spatial directions are called 3D nonlinear photonic crystals (NPhCs). They enable enhanced nonlinear optical conversion efficiencies, emission control, and simultaneous generation of nonlinear wavelengths. The chemical inertness of efficient second‐order nonlinear materials (χ(2)) prohibits their nanofabrication until 2018. The current methods are restricted to top‐down laser‐based techniques limiting the periodicity along the z‐axis to 10 μm. The first bottom‐up fabricated 3D NPhC is demonstrated in sol–gel‐derived barium titanate by soft‐nanoimprint lithography: a woodpile with eight layers and periodicities of 1 μm (xy‐plane) and 300 nm (z‐plane). The surface areas exceed 5.3×104 μm2, which is two orders of magnitude larger than the state‐of‐the‐art. This study is expected to initiate bottom‐up fabrication of 3D NPhCs with a supremely strong and versatile nonlinear response.

Published in Advanced Photonics Research

ISSN: 2699-9293 (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Technology: Engineering (General). Civil engineering (General): Applied optics. Photonics; Science: Physics: Optics. Light
Website: https://onlinelibrary.wiley.com/journal/26999293

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