SubsidieMeestersChallenging the fundamental limit of angular dispersion by hybridizing light and matter
HyAngle aims to break the angular dispersion limit in optics by hybridizing light and matter, developing angle-independent optical devices for advanced imaging and display applications.
Projectdetails
Introduction
Interference is one of the most fundamental phenomena in optics, allowing us to confine, filter, manipulate, and steer light with exquisite precision. It is at the core of thin-film optics and nanophotonics, two areas of science that catalyze major scientific and industrial advances.
Angular Dispersion Limitation
One fundamental property of optical interference, however, constitutes a major limitation – the characteristics of any interference-based structure depend on the angle between the light wave and the structure itself. For example, the transmission wavelength of optical interference filters shifts strongly when the angle of incidence changes. So far, this ‘angular dispersion’ effect remains a largely unchallenged fundamental limit in optics.
Proposed Strategy
HyAngle now proposes a novel strategy based on hybridizing light and matter states to break the angular dispersion limit. By tuning the coupling strength and offset between a photonic resonance formed by optical interference and the electronic resonance causing optical absorption in a material, we expect to realize interference-based optical devices with:
- Spectrally sharp transmission
- Angle-independent reflection
- Angle-independent emission
Research Focus
We will explore the physics, potential, and limitations of this approach by developing and studying:
- Dispersion-free optical filters
- Colour converters
- LEDs with narrowband spectra
Applications
We will then pursue two specific applications:
- Hyperspectral cameras
- Bio-implantable lensless fluorescence microscopes
Our devices will enable major advances in capability and unprecedented performance in deep tissue applications.
Material Compatibility
Our devices use organic materials that can be readily processed by high-throughput vacuum deposition and even from solution. The amorphous nature of these materials renders them intrinsically compatible with the dielectric and metallic films widely used in the optics and display industry.
Conclusion
The strategy of HyAngle thus bears great potential for rapid development and broad application.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.500.000 |
| Totale projectbegroting | € 2.500.000 |
Tijdlijn
| Startdatum | 1-12-2023 |
| Einddatum | 30-11-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- UNIVERSITAT ZU KOLNpenvoerder
Land(en)
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Stable Polariton LiDAR
The SPLiDAR project aims to develop angle-independent polariton filters to overcome angular dispersion limitations in LiDAR systems, enhancing optical filtering and 3D sensing applications.
Maskless Surface morphing by Holographic Hyper Lithography
HyperMaSH aims to revolutionize photonic technology by developing a high-resolution, environmentally friendly lithographic method for advanced planar optical components using vector-time-color hyper lithography.
Bioinspired composite architectures for responsive 4 dimensional photonics
BIO4D aims to create biomimetic 3D photonic structures using self-ordering nanomaterials and advanced fabrication to enable dynamic optical responses for various applications.
Controlling spin angular momentum with the field of light
The project aims to unveil direct light-spin interactions using attosecond pulses to control angular momentum in materials, enhancing understanding of magnetism and enabling ultrafast optical device design.
Fluidic Shaping of Optical Components on Earth and in Space
The project aims to develop Fluidic Shaping for rapid, high-precision optical component fabrication using liquid interfaces, enhancing accessibility in various fields including space exploration and astronomy.
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