Imaging surface plasmon polaritons using proximal self-assembled InGaAs quantum dots

TL;DR

This paper demonstrates a novel optical imaging technique for surface plasmon polaritons using quantum dots on GaAs substrates, enabling real-space visualization and analysis of plasmonic modes and beam splitters.

Contribution

It introduces a method to image propagating surface plasmon polaritons via quantum dot luminescence, with precise control of quantum dot placement and validation through simulations.

Findings

Different plasmonic modes observed at waveguide ends.

Splitting ratio of 50:50 at specific interaction length.

Good agreement between experimental results and simulations.

Abstract

We present optical investigations of hybrid plasmonic nanosystems consisting of lithographically defined plasmonic Au-waveguides or beamsplitters on GaAs substrates coupled to proximal self-assembled InGaAs quantum dots. We designed a sample structure that enabled us to precisely tune the distance between quantum dots and the sample surface during nano-fabrication and demonstrated that non-radiative processes do not play a major role for separations down to $\sim 10 nm$. A polarized laser beam focused on one end of the plasmonic nanostructure generates propagating surface plasmon polaritons that, in turn, create electron-hole pairs in the GaAs substrate during propagation. These free carriers are subsequently captured by the quantum dots $\sim 25 nm$ below the surface, giving rise to luminescence. The intensity of the spectrally integrated quantum dot luminescence is used to image the propagating plasmon modes. As the waveguide width reduces from $5 \mu m$ to $1 \mu m$, we clearly observe different plasmonic modes at the remote waveguide end, enabling their direct imaging in real space. This imaging technique is applied to a plasmonic beamsplitter facilitating the determination of the splitting ratio between the two beamsplitter output ports as the interaction length $L_i$ is varied. A splitting ratio of $50:50$ is observed for $L_i\sim 9\pm1 \mu m$ and $1 \mu m$ wide waveguides for excitation energies close to the GaAs band edge. Our experimental findings are in good agreement with mode profile and finite difference time domain simulations for both waveguides and beamsplitters.