Metal-coated microsphere monolayers as surface plasmon resonance sensors operating in both transmission and reflection modes

TL;DR

This paper introduces silver-coated polystyrene microsphere monolayers as dual-mode surface plasmon resonance sensors, revealing a secondary transmission band with higher sensitivity and demonstrating the impact of adsorbate location on sensing efficiency.

Contribution

The study demonstrates the use of smaller colloids to observe a new transmission band and compares transmission and reflection modes for enhanced plasmonic sensing.

Findings

Secondary optical transmission band exhibits higher sensitivity.

Reflection mode is nearly ten times more efficient than transmission mode.

Adsorbate location significantly affects sensing performance.

Abstract

Metal-coated microsphere monolayers (MCM) are a class of plasmonic crystals consisting of noble metal films over arrays of self-assembled colloidal microspheres. Despite their ease of fabrication and tunable plasmonic response, their optical sensing potential has been scarcely explored. Here, silver coated polystyrene sphere monolayers are proposed as surface plasmon resonance sensors capable of functioning in both transmission (T) and reflection (R) readout modes. An original and key point is the use of ~200 nm colloids, smaller than in MCM studied before. It allowed us to reveal a previously unobserved, additional/secondary Enhanced Optical Transmission band, which can be exploited in sensing, with higher sensitivity than the better-known main transmission band. The reflection configuration however, is almost an order of magnitude more efficient for sensing than the transmission one. We also evidenced a strong impact of the adsorbate location on the metal surface on the sensing efficiency. Electric field distribution analysis is performed to explain these results. Proof-of-concept experiments on the detection of 11-MUA molecular monolayers, performed in both readout modes, confirm the behaviors observed through FDTD simulations. Results in this paper can serve as guidelines for designing optimized sensors based on metal-coated colloidal monolayers, and more generally for plasmonic sensors based on metal nanostructured films.