Numerical analysis. a Simulation model of a unit cell for the infinitely periodic metasurface consisting of a-Si resonators. b Calculated transmittance and c TH intensity (log scale) maps as a function of elliptical diameters dx and dy of the resonator. The colored curves plotted in both maps highlight the paths of the FF mode resonances (b). d, e Calculated electric near-field plots of modes for different resonators with diameters indicated by points in the maps at (d) pump 1560鈥塶m and (e) TH 520鈥塶m wavelengths. The periodicity of the unit cell and the resonator height are p鈥�=鈥�916.7鈥塶m and h鈥�=鈥�590鈥塶m, respectively. The maximum of the generated TH is indicated by the dot with label Super-Fano in both maps for the resonator with diameters dx鈥�=鈥�740鈥塶m and dy鈥�=鈥�550鈥塶m. Credit: Light: Science & Applications (2023). DOI: 10.1038/s41377-023-01134-1

Natural and artificial crystals can change the spectral color of light, which is known as the nonlinear optical effect. Color conversion is used for numerous applications, including nonlinear microscopy for biological structures and material examinations, LED light sources and lasers in optical communications, and in photonics and its resulting technologies such as quantum computing. Researchers from Paderborn University have now found a way to improve the physical process underlying the phenomenon. The results have been published in the journal Light: Science & Applications.

"The process is based on the anharmonic potential of crystal atoms and often prompts a precise multiplication of the light frequency, known as generating 'higher harmonics'鈥攕imilar to the overtones heard when the string on a vibrates," Paderborn physicist Professor Cedrik Meier explains.

Although the effect occurs naturally in many crystals, it is often extremely weak. Given this, there have been various approaches to increasing the effect, for example by combining different materials and their structures on a micro and nano scale. Paderborn University has conducted intensive, successful research in this area in recent decades.

One focal point of this research into photonics is metamaterials, and in particular metasurfaces. This involves structured elements being applied in the nanometer range to a thin substrate, which then interacts with incoming light and for example produces optical resonances. With a longer duration and greater focus, the light can generate higher harmonics more efficiently.

An sees the research groups run by Professor Cedrik Meier (Nanophotonics & Nanomaterials), Professor Thomas Zentgraf (Ultrafast Nanophotonics) and Professor Jens F枚rstner (Theoretical Electrical Engineering) at Paderborn University working together as part of the "Tailored Nonlinear Photonics" Collaborative Research Center/Transregio 142 to develop an innovative approach to generating higher harmonics more efficiently. By using specifically proportioned applications of microscopically small elliptical cylinders made of silicon, they can take advantage of the Fano effect鈥攁 particular physical mechanism where multiple resonances intensify each other.

The researchers initially used digital simulation to determine the ideal geometric parameters and investigated the underlying physics. They then created nanostructures using state-of-the-art lithography processes, and conducted optical examinations. They were able to prove through both theory and experimentation that this enables third harmonics鈥攊.e., light with triple the frequency of the incoming light鈥攖o be generated much more efficiently than with previous known structures.

More information: David H盲hnel et al, A multi-mode super-fano mechanism for enhanced third harmonic generation in silicon metasurfaces, Light: Science & Applications (2023).

Journal information: Light: Science & Applications

Provided by Universit盲t Paderborn