Author
Listed:
- Andreas Heßler
(RWTH Aachen University)
- Sophia Wahl
(RWTH Aachen University)
- Till Leuteritz
(University of Bonn)
- Antonios Antonopoulos
(RWTH Aachen University)
- Christina Stergianou
(RWTH Aachen University)
- Carl-Friedrich Schön
(RWTH Aachen University)
- Lukas Naumann
(University of Bonn)
- Niklas Eicker
(RWTH Aachen University)
- Martin Lewin
(RWTH Aachen University)
- Tobias W. W. Maß
(RWTH Aachen University)
- Matthias Wuttig
(RWTH Aachen University)
- Stefan Linden
(University of Bonn)
- Thomas Taubner
(RWTH Aachen University)
Abstract
The high dielectric optical contrast between the amorphous and crystalline structural phases of non-volatile phase-change materials (PCMs) provides a promising route towards tuneable nanophotonic devices. Here, we employ the next-generation PCM In3SbTe2 (IST) whose optical properties change from dielectric to metallic upon crystallization in the whole infrared spectral range. This distinguishes IST as a switchable infrared plasmonic PCM and enables a programmable nanophotonics material platform. We show how resonant metallic nanostructures can be directly written, modified and erased on and below the meta-atom level in an IST thin film by a pulsed switching laser, facilitating direct laser writing lithography without need for cumbersome multi-step nanofabrication. With this technology, we demonstrate large resonance shifts of nanoantennas of more than 4 µm, a tuneable mid-infrared absorber with nearly 90% absorptance as well as screening and nanoscale “soldering” of metallic nanoantennas. Our concepts can empower improved designs of programmable nanophotonic devices for telecommunications, (bio)sensing and infrared optics, e.g. programmable infrared detectors, emitters and reconfigurable holograms.
Suggested Citation
Andreas Heßler & Sophia Wahl & Till Leuteritz & Antonios Antonopoulos & Christina Stergianou & Carl-Friedrich Schön & Lukas Naumann & Niklas Eicker & Martin Lewin & Tobias W. W. Maß & Matthias Wuttig , 2021.
"In3SbTe2 as a programmable nanophotonics material platform for the infrared,"
Nature Communications, Nature, vol. 12(1), pages 1-10, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-21175-7
DOI: 10.1038/s41467-021-21175-7
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