Photoluminescence enhancement at the vertical van der Waals semiconductor-metal heterostructures

TL;DR

This paper demonstrates a simple vertical heterostructure approach to significantly enhance photoluminescence in monolayer TMDCs by suppressing nonradiative decay and leveraging plasmonic effects, advancing optoelectronic device performance.

Contribution

It introduces a vertical vdW metal-TMDC heterostructure method for PL enhancement, highlighting interface properties and exciton dynamics as key factors.

Findings

PL enhancement of over an order of magnitude

Suppressed exciton quenching due to vdW interface

Reduced exciton-exciton annihilation at high excitation powers

Abstract

Excitons in monolayer transition metal dichalcogenides (TMDCs) offer intriguing new possibilities for optoelectronics with no analogues in bulk semiconductors. Yet, intrinsic defects in TMDCs limit the radiative exciton recombination pathways. As a result, the photoluminescence (PL) quantum yield (QY) is limited. Methods like superacid treatment, electrical doping, and plasmonic engineering can inhibit nonradiative decay channels and enhance PL. Here, we show a more straightforward approach that allows PL enhancement. An engineered vertical van der Waals (vdW) metal-monolayer semiconductor junction (MSJ) results in PL enhancement of more than an order of magnitude at technologically relevant excitation powers. Such MSJ can be constructed by vertically stacking metals with suitable work function either above or below a monolayer semiconducting TMDC. Our experiments reveal that the underlying PL enhancement mechanism is to be the suppressed exciton quenching due to the absence of metal-induced gap states and weak Fermi level pinning, thanks to the vdW gapped interface between the metal and the TMDC. Our time-resolved PL measurements further indicate that reduced exciton-exciton annihilation, even at high generation rates, contributes to the observed PL enhancement. The PL intensity is further increased by the proximity of surface plasmons in the metal with the TMDC layer. Our findings shed light on the interaction at vdW metal-semiconductor interfaces and offer a path to improving the optoelectronic performance of semiconducting TMDCs.