Engineered sers substrates employing nanoparticle cluster arrays with multiscale signal enhancement

Abstract

Defined nanoparticle cluster arrays (NCAs) with total lateral dimensions of up to 25.4 μm by 25.4 μm have been fabricated on top of a 10 nm thin gold film using template guided self-assembly. This approach provides precise control of the structural parameters in the arrays allowing a systematic variation of the average number of nanoparticles in the clusters (n) and the edge to edge separation (Λ) between 1<n<20 and 50 nm≦Λ≦1000 nm, respectively. Investigations of the Rayleigh scattering spectra and surface enhanced Raman scattering (SERS) signal intensities as a function of n and Λ reveal direct near-field coupling between the particles within individual clusters, whose strength increases with the cluster size (n) until it saturates at around n=4. Our analysis shows that strong near-field interactions between individual clusters significantly affects the SERS signal enhancement for edge-to-edge separations Λ<200 nm. The observed dependencies of the Raman signals on n and Λ indicate that NCAs support a multiscale signal enhancement which originates from simultaneous inter- and intra-cluster coupling and |E|-field enhancement. The NCAs provide strong SERS signals of bacterial cells thus enabling a rapid and reliable spectral identification of bacteria.