Enhanced Raman and photoluminescence response in monolayer MoS2 due to laser healing of defects

Abstract

Bound quasiparticles, negatively charged trions and neutral excitons, are associated with the direct optical transitions at the K-points of the Brillouin zone for monolayer MoS2. The change in the carrier concentration, surrounding dielectric constant and defect concentration can modulate the photoluminescence and Raman spectra. Here we show that exposing the monolayer MoS2 in air to a modest laser intensity for a brief period of time enhances simultaneously the photoluminescence (PL) intensity associated with both trions and excitons, together with 3 to 5 times increase of the Raman intensity of first and second order modes. The simultaneous increase of PL from trions and excitons cannot be understood based only on known-scenario of depletion of electron concentration in MoS2 by adsorption of O2 and H2O molecules. This is explained by laser induced healing of defect states resulting in reduction of non-radiative Auger processes. This laser healing is corroborated by an observed increase of intensity of both the first order and second order 2LA(M) Raman modes by a factor of 3 to 5. The A1g mode hardens by 1.4 cm-1 whereas the E12g mode softens by 1 cm-1. The second order 2LA(M) Raman mode at 440 cm-1 shows an increase in wavenumber by 8 cm-1 with laser exposure. These changes are a combined effect of change in electron concentrations and oxygen-induced lattice displacements.