Non-primitive hybrid metasurfaces based on disordered plasmonic networks and dielectric nanocups.
Strong coupling in a disordered metamaterial, realized solely by self-assembly.
Disorder as a design parameter to create a new class of metamaterials with a wide range of funcitionalities.
We present a method that provides direct optical feedback on the thickness and crystallinity of sputter-deposited MoS2 down to the few-layer regime.
In this work, Ag/a-Si multilayers are examined as a model system for the thermal stability of hyperbolic metamaterials.
We illustrate the capabilities of metal-induced crystallization in disordered metasurfaces as alternative platform for large area epsilon-near-zero (ENZ) materials.
We present a comprehensive analysis of the optical properties of chocolates.
We utilize phase‐changing germanium antimony tellurium (GST) compounds as functional coatings on PET and Vectran fibers.
The photo-activated pattern formation on azobenzene polymer films is explained by the physical concept of phase separation.
Highly abundant oxygen-rich line defects can act as fast oxygen transport paths during catalysis.
Pt-alloy catalyst with enhanced activity and stability.
A thermally self-sustained µSOFC based micro-power plant.
Dewetting of platinum on dielectric substrates.

Plasmonic Networks

Using various forms of self-assembly at the nanoscale, we aim to assemble perfect absorbing light-harvesting systems based on network metamaterials. Similarly to complex systems, network metamaterials are based on the connectivity among a large number of fully heterogeneous units, which are arranged in disordered networks. Despite the lack of both symmetry and long-range order, these systems possess complex light-matter interactions, generating an ensemble of surface plasmon (SP) waves that, due to nanoscaled disorder, are not able to propagate and acquire the character of localized waves. The local subwavelength confinement of light leads to the formation of controllable absorbing states, tunable in a large optical window and originating in ultra-thin material regions.

Scalable Metamaterials

The design and fabrication of large-area metamaterials is an ongoing challenge. We utilized solid state reactions, such as localized crystallization, to generate truly scalable metamatarials and metasurfaces with new functional properties. Especially in anisotropic systems, such as hyperbolic metamaterials, these reactions compete with thermal instabilities. We aim to identify the underlying physics of this competition to assist the informed design of metamaterials for high-temperature applications.

Structural Color Sensors

We humans constantly use colour to assess our surroundings. We build on the same principle and use the generation of structural colours to gauge a material’s properties. Color changes observed by eye or simple optical measurements provide the means to monitor the temporal evolution of functional properties e.g. in high-performance polymers fibers, phase change materials or transition metal nitride coatings. Furthermore, foodgrade optical coatings offer unique ways to colour complex optical materials, such as chocolate.

Publications