Insights into hyperbolic phonon polaritons in hBN using Raman scattering from encapsulated transition metal dichalcogenide layers

TL;DR

This paper explores hyperbolic phonon polaritons in hBN using Raman scattering techniques enhanced by encapsulated transition metal dichalcogenide layers, revealing new resonances and physics beyond current understanding.

Contribution

It demonstrates new Raman scattering methods to probe HPP in hBN with enhanced wavevectors and frequencies, uncovering previously unknown phenomena.

Findings

Raman scattering probes HPP with wavevectors >15000 cm-1

Enhanced resonances observed in WSe2 and MoSe2 monolayers

Evidence of HPP physics below the expected lower bound

Abstract

New techniques for probing hyperbolic phonon polaritons (HPP) in 2D materials will support the development of the emerging technologies in this field. Previous reports have shown that it is possible for WSe2 monolayers in contact with the hexagonal boron nitride (hBN) to generate HPP in the hBN via Raman scattering. In this paper, we set out new results on HPP Raman scattering induced in hBN by WSe2 and MoSe2 monolayers including new resonances at which the Raman scattering is enhanced. Analysis of the observed Raman lineshapes demonstrates that Raman scattering allows HPP with wavevectors with magnitudes significantly in excess of 15000 cm-1 to be probed. We present evidence that the Raman scattering can probe HPP with frequencies less than the expected lower bound on the Reststrahlen band suggesting new HPP physics still waits to be discovered.