Exciton and Phonon Radiative Linewidths in Monolayer Boron Nitride

The light-matter interaction in bulk semiconductors is in the strong-coupling regime with hybrid eigenstates, the so-called exciton polaritons and phonon polaritons. In two-dimensional (2D) systems, the translational invariance is broken in the direction perpendicular to the plane of the 2D system. The light-matter interaction switches to the weak-coupling regime with a finite radiative lifetime of the matter excitations in 2D. Radiative phenomena have been extensively studied for 2D excitons in quantum wells and 2D crystals, but their counterpart has never been addressed for optical phonons in 2D. Here we present a parallel study of the exciton and phonon radiative linewidths in atomically thin layers of hexagonal boron nitride (h-BN), epitaxially grown on graphite. Reflectivity experiments are performed either in the deep ultraviolet for the excitonic resonance or in the midinfrared for the phononic one. A quantitative interpretation is implemented in the framework of a transfer matrix approach generalized to the case of monolayers with the inclusion of Breit-Wigner resonances of either excitonic or phononic nature. For the exciton we find a giant radiative broadening in comparison to other 2D crystals, with a value of similar to 25 meV related to the strong excitonic effects in h-BN. For the phonon we provide the first estimation of the radiative linewidth of a 2D phonon, with a value of similar to 0.2 meV in monolayer h-BN. Our results are found to be in good agreement with first-principles calculations. Our study unravels the existence of radiative states for optical phonons in 2D, with numerous perspectives for fundamental physics, optoelectronic applications in the midinfrared spectral range, and advanced thermal management, and h-BN is emerging as a model system in this novel topic.

Automated summary

In this study, parallel investigation of exciton and phonon radiative linewidths in atomically thin layers of hexagonal boron nitride (h-BN) was conducted, revealing a significant radiative broadening in the two-dimensional material and indicating the existence of radiative states for optical phonons in 2D. This finding has important implications for fundamental physics and optoelectronic applications.