# Integration of atomically thin layers of transition metal   dichalcogenides into high-Q, monolithic Bragg-cavities - an experimental   platform for the enhancement of optical interaction in 2D-materials

**Authors:** Heiko Knopf, Nils Lundt, Tobias Bucher, Sven H\"Ofling, Sefaattin, Tongay, Takashi Taniguchi, Kenji Watanabe, Isabelle Staude, Ulrike Schulz,, Christian Schneider, Falk Eilenberger

arXiv: 1812.00634 · 2018-12-06

## TL;DR

This paper presents an experimental platform integrating atomically thin transition metal dichalcogenides into high-Q monolithic Bragg-cavities, enabling enhanced and tunable light-matter interactions in 2D materials.

## Contribution

It introduces a novel ion-assisted vapor deposition method for embedding 2D materials into high-Q cavities without degrading their optical properties.

## Key findings

- Achieved a Q-factor exceeding 4500 in the monolithic resonator.
- Demonstrated that the integration process preserves the electrooptical properties of 2D materials.
- Observed resonance-induced modifications in photoluminescence spectra.

## Abstract

We demonstrate a new approach to integrate single layer MoSeR2R and WSeR2R flakes into monolithic all-dielectric planar high-quality micro-cavities. These distributed-Bragg-reflector (DBR) cavities may e.g. be tuned to match the exciton resonance of the 2D-materials. They are highly robust and compatible with cryogenic and room-temperature operation. The integration is achieved by a customized ion-assisted physical vapor deposition technique, which does not degrade the optical properties of the 2D-materials. The monolithic 2D resonator is shown to have a high Q-factor in excess of 4500. We use photoluminescence (PL) experiments to demonstrate that the coating procedure with an SiO2 coating on a prepared surface does not significantly alter the electrooptical properties of the 2D-materials. Moreover, we observe a resonance induced modification of the PL-spectrum for the DBR embedded flake. Our system thus represents a versatile platform to resonantly enhance and tailor light-matter-interaction in 2D-materials. The gentle processing conditions would also allow the integration of other sensitive materials into these highly resonant structures.

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Source: https://tomesphere.com/paper/1812.00634