# Control of LED Emission with Functional Dielectric Metasurfaces

**Authors:** Egor Khaidarov, Zhengtong Liu, Ramon Paniagua-Dominguez, Son Tung Ha,, Vytautas Valuckas, Xinan Liang, Yuriy Akimov, Ping Bai, Ching Eng Png, Hilmi, Volkan Demir, Arseniy I. Kuznetsov

arXiv: 1907.08329 · 2020-03-10

## TL;DR

This paper introduces a novel cavity-based approach to enhance the spatial coherence of LED emission, enabling precise wavefront control with metasurfaces without reducing emitted power, demonstrated on a GaP LED with advanced functionalities.

## Contribution

It proposes a cavity integration method to improve LED coherence for metasurface applications, allowing complex light manipulation without power loss, and demonstrates this with directional and vortex beam emission.

## Key findings

- Enhanced LED coherence via cavity design
- Successful demonstration of directional emission
- Generation of vortex beams with orbital angular momentum

## Abstract

The improvement of light-emitting diodes (LEDs) is one of the major goals of optoelectronics and photonics research. While emission rate enhancement is certainly one of the targets, in this regard, for LED integration to complex photonic devices, one would require to have, additionally, precise control of the wavefront of the emitted light. Metasurfaces are spatial arrangements of engineered scatters that may enable this light manipulation capability with unprecedented resolution. Most of these devices, however, are only able to function properly under irradiation of light with a large spatial coherence, typically normally incident lasers. LEDs, on the other hand, have angularly broad, Lambertian-like emission patterns characterized by a low spatial coherence, which makes the integration of metasurface devices on LED architectures extremely challenging. A novel concept for metasurface integration on LED is proposed, using a cavity to increase the LED spatial coherence through an angular collimation. Due to the resonant character of the cavity, extending the spatial coherence of the emitted light does not come at the price of any reduction in the total emitted power. The experimental demonstration of the proposed concept is implemented on a GaP LED architecture including a hybrid metallic-Bragg cavity. By integrating a silicon metasurface on top we demonstrate two different functionalities of these compact devices: directional LED emission at a desired angle and LED emission of a vortex beam with an orbital angular momentum. The presented concept is general, being applicable to other incoherent light sources and enabling metasurfaces designed for plane waves to work with incoherent light emitters.

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Source: https://tomesphere.com/paper/1907.08329