# Quantum light in curved low dimensional hexagonal boron nitride systems

**Authors:** Nathan Chejanovsky, Youngwook Kim, Andrea Zappe, Benjamin Stuhlhofer,, Takashi Taniguchi, Kenji Watanabe, Durga Bhaktavatsala Rao Dasari, Amit, Finkler, Jurgen H. Smet, J\"org Wrachtrup

arXiv: 1705.00029 · 2017-11-17

## TL;DR

This study explores quantum emitters in curved, low-dimensional hexagonal boron nitride systems, revealing stable quantum emitters in BN nanotubes and their potential for quantum optics applications.

## Contribution

It demonstrates the presence of stable quantum emitters in BN nanotubes and links curvature to quantum emitter formation, providing a new platform for quantum optics research.

## Key findings

- BN nanotubes host abundant stable quantum emitters
- Quantum emitters are localized at sub-20 nm scales
- Curvature influences quantum emitter spectral features

## Abstract

Low-dimensional wide bandgap semiconductors open a new playing field in quantum optics using sub-bandgap excitation. In this field, hexagonal boron nitride (h-BN) has been reported to host single quantum emitters (QEs), linking QE density to perimeters. Furthermore, curvature/perimeters in transition metal dichalcogenides (TMDCs) have demonstrated a key role in QE formation. We investigate a curvature-abundant BN system - quasi one-dimensional BN nanotubes (BNNTs) fabricated via a catalyst-free method. We find that non-treated BNNT is an abundant source of stable QEs and analyze their emission features down to single nanotubes, comparing dispersed/suspended material. Combining high spatial resolution of a scanning electron microscope, we categorize and pin-point emission origin to a scale of less than 20 nm, giving us a one-to-one validation of emission source with dimensions smaller than the laser excitation wavelength, elucidating nano-antenna effects. Two emission origins emerge: hybrid/entwined BNNT. By artificially curving h-BN flakes, similar QE spectral features are observed. The impact on emission of solvents used in commercial products and curved regions is also demonstrated. The 'out of the box' availability of QEs in BNNT, lacking processing contamination, is a milestone for unraveling their atomic features. These findings open possibilities for precision engineering of QEs, puts h-BN under a similar 'umbrella' of TMDC's QEs and provides a model explaining QEs spatial localization/formation using electron/ion irradiation and chemical etching.

---
Source: https://tomesphere.com/paper/1705.00029