# Enhancement of the Monolayer WS2 Exciton Photoluminescence with a   2D-Material/Air/GaP In-Plane Microcavity

**Authors:** Oliver Mey, Franziska Wall, Lorenz Maximilian Schneider, Darius, G\"under, Frederik Walla, Amin Soltani, Hartmut G. Roskos, Ni Yao, Peng Qing,, Wei Fang, and Arash Rahimi-Iman

arXiv: 1812.10286 · 2018-12-27

## TL;DR

This paper demonstrates a novel 2D-material/air/GaP in-plane microcavity that significantly enhances monolayer WS2 photoluminescence by a factor of 10 through interference effects in both horizontal and vertical directions.

## Contribution

It introduces a unique optical microcavity design combining circular Bragg grating and multilayer reflection to optimize light confinement and enhance photoluminescence in monolayer WS2.

## Key findings

- Photoluminescence of WS2 enhanced by a factor of 10
- Effective in-plane and out-of-plane light confinement achieved
- Optimized etch depth for maximum constructive interference

## Abstract

Light-matter interaction with two-dimensional materials gained significant attention in recent years leading to the reporting of weak and strong coupling regimes, and effective nano-laser operation with various structures. Particularly, future applications involving monolayer materials in waveguide-coupled on-chip integrated circuitry and valleytronic nanophotonics require controlling, directing and optimizing photoluminescence. In this context, photoluminescence enhancement from monolayer transition-metal dichalcogenides on patterned semiconducting substrates becomes attractive. It is demonstrated in our work using focussed-ion-beam-etched GaP and monolayer WS2 suspended on hexagonal-BN buffer sheets. We present a unique optical microcavity approach capable of both efficient in-plane and out-of-plane confinement of light, which results in a WS2 photoluminescence enhancement by a factor of 10 compared to the unstructured substrate at room temperature. The key concept is the combination of interference effects in both the horizontal direction using a bull's-eye-shaped circular Bragg grating and in vertical direction by means of a multiple reflection model with optimized etch depth of circular air-GaP structures for maximum constructive interference effects of the applied pump and expected emission light.

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Source: https://tomesphere.com/paper/1812.10286