Control of LED radiation with functional dielectric metasurfaces
Light-emitting diodes (LEDs) are excellent candidates to replace the widespread conventional fluorescent light sources. This stems from their higher compactness and brightness, as well as their better performance in terms of energy efficiency, long lifetime and high color rendering qualities. The...
Saved in:
| Main Author: | |
|---|---|
| Other Authors: | |
| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2020
|
| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/137392 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Light-emitting diodes (LEDs) are excellent candidates to replace the widespread
conventional fluorescent light sources. This stems from their higher compactness
and brightness, as well as their better performance in terms of energy efficiency,
long lifetime and high color rendering qualities. Their potential use in a
broad range of applications has attracted enormous interest to the LED research
and development. This has translated to a rapid improvement of the LED
characteristics as well as to their commercialization in past years. Further
integration and miniaturization of these devices, for applications such as optical
communications, requires a higher level of control in terms of LED emission
characteristics and a compact solution for any desired functionality on the
output. Metasurfaces (structured surfaces with engineered characteristics)
grant an unprecedented control over the wavefront of light, while retaining a
subwavelength-thickness feature (relative to the excitation light wavelength).
Moreover, in some cases, they also offer opportunities for large-scale industrial
fabrication. Among different types of the metasurfaces, those based on dielectric
and semiconductor materials typically exhibit lower losses comparing to metallic
counterparts, which potentially enhances the efficiency of their integrated
devices.
The main focus of this dissertation is to develop and demonstrate the compact
and novel LED platforms, with light emission characteristics on demand,
enabled by means of dielectric metasurfaces. For this purpose, highly efficient
metasurfaces based on dielectric and semiconductor materials (Si, TiO2, GaN) have been designed and fabricated. The functionalities realized with these include
beam deflectors, polarization beam splitters, complex light field generators
and lenses. For the latter, a novel class of metasurfaces with asymmetric
radiation profile was engineered. With them, light channeling into a single
desired diffractive order has been achieved with efficiencies reaching 99%.
Ultra-high angle beam deflection metasurfaces operating in the visible regime
were demonstrated using TiO2 for the blue and green and Si for the red part of the
spectrum. Based on this concept, a near unity numerical aperture (NA) lens was
designed and fabricated, far exceeding any previously reported, both commercial
and laboratory experimental models.
Moving towards direct metasurface integration on conventional LED
platforms, GaN metasurfaces were etched directly into optically thick GaN
slabs. Despite the low index contrast between the patterned metasurface and
its substrate (both GaN), the metasurfaces exhibited high efficiencies across the
operational wavelength range of the LED emission. However, when excited
directly with the photoluminescence from the LED, the desired functionality was
lost due to the low spatial coherence (Lambertian shape of radiation pattern) of
the LED. Hence, the approach for direct integration of the metasurface on top of
LED was found to be inefficient.
To solve this issue, external and internal cavity design solutions for
the LED and metasurface integration were proposed and engineered. The
efficient transformation of the Lambertian radiation pattern into plane-wave-like
radiation, suitable for the metasurface to work, was experimentally demonstrated.
Further integration with the designed metasurfaces allowed to obtain advanced
functionalities for the LED emitted light, namely beam deflection and vortex
beam generation. Those were realized in a GaP LED architecture via optical
pumping. The electrically-driven GaN LED device with a beam deflection
functionality was demonstrated using the external cavity method.
The results presented in this dissertation constitute a step forward towards compact, advanced, efficient and integrated optical devices, by leveraging on
the attractive platform of LEDs and the emerging field of metasurfaces, which
enables unprecedented control of light. The method proposed can be applied to
any other incoherent light source beyond LEDs, and may find broad applications
in optical communications, Li-Fi, displays, sensing, smart lighting and many
more. |
|---|