Exciton states in monolayer MoSe2 and MoTe2 probed by upconversion spectroscopy

TL;DR

This study reveals excited exciton states in monolayer MoSe2 and MoTe2 using upconversion spectroscopy, showing how encapsulation improves spectral resolution and enables detailed investigation of these high-energy states.

Contribution

The paper demonstrates the first observation of excited exciton states in MoSe2 and MoTe2 monolayers via upconversion spectroscopy, facilitated by improved sample quality through encapsulation.

Findings

Excited exciton states observed up to 200 meV above the laser energy.

Encapsulation reduces emission linewidths to below 1.5 meV and 3 meV.

Bias control influences upconversion efficiency.

Abstract

Transitions metal dichalcogenides (TMDs) are direct semiconductors in the atomic monolayer (ML) limit with fascinating optical and spin-valley properties. The strong optical absorption of up to 20 % for a single ML is governed by excitons, electron-hole pairs bound by Coulomb attraction. Excited exciton states in MoSe$_2$ and MoTe$_2$ monolayers have so far been elusive due to their low oscillator strength and strong inhomogeneous broadening. Here we show that encapsulation in hexagonal boron nitride results in emission line width of the A:1$s$ exciton below 1.5 meV and 3 meV in our MoSe$_2$ and MoTe$_2$ monolayer samples, respectively. This allows us to investigate the excited exciton states by photoluminescence upconversion spectroscopy for both monolayer materials. The excitation laser is tuned into resonance with the A:1$s$ transition and we observe emission of excited exciton states up to 200 meV above the laser energy. We demonstrate bias control of the efficiency of this non-linear optical process. At the origin of upconversion our model calculations suggest an exciton-exciton (Auger) scattering mechanism specific to TMD MLs involving an excited conduction band thus generating high energy excitons with small wave-vectors. The optical transitions are further investigated by white light reflectivity, photoluminescence excitation and resonant Raman scattering confirming their origin as excited excitonic states in monolayer thin semiconductors.