Nanogap-Engineered Core-Shell-Like Nanostructures for Comprehensive SERS Analysis

TL;DR

This paper presents a simple, scalable method to fabricate large-area plasmonic nanostructures with tunable sub-10 nm gaps, enabling highly uniform and sensitive SERS analysis suitable for real-world applications.

Contribution

A novel cleanroom-free fabrication protocol for macroscopic plasmonic substrates with controllable nanogaps and multi-resonance optical responses for enhanced SERS performance.

Findings

Achieved spatial uniformity with RSD of 1.9% in SERS signals.

Enhanced SERS sensitivity with an EF of approximately 10^6.

Demonstrated stability and reproducibility across multiple substrates.

Abstract

Development of fabrication protocols for large-area plasmonic nanostructures with sub-10 nm gaps with a spatially controlled distribution is critical for their real-world applications. In this work, we develop a simple, cleanroom-free protocol for the fabrication of macroscopic-sized plasmonic substrates (>6 cm^2), featuring a tunable multi-resonance optical response and light concentration in sub-10 nm gaps. Critically, these gaps are free to interact with the surrounding medium. This architecture consists of non-periodically distributed dielectric nanospheres coated with a metal multilayer, forming semi-spherical core-shell-like nanostructures (CSLNs) surrounded by a planar film. The sub-10 nm gaps formed between metal caps and the planar film are easily tuned by adjusting fabrication parameters such as multimetal layer thickness, composition, or nanosphere size and density. The excellent structural homogeneity, wide optical tunability, and extreme light confinement in the spatially controlled subwavelength nanogaps make CSLN-based substrates an ideal platform for comprehensive surface-enhanced Raman scattering (SERS) spectroscopy. This is proven through a combination of numerical modeling and iterative fabrication/characterization, leading to the optimized substrates showing cutting-edge spatial uniformity down to 1.9% determined as the relative standard deviation (RSD) of the SERS signal of p-mercaptobenzoic acid for 225 spectra over 3600 {\mu}m^2 area. High sensitivity is evidenced by an enhancement factor of ~10^6. The proposed substrates also meet all other demanding criteria, including sufficient signal temporal stability (RSD <4%), high substrate-to-substrate reproducibility (<15%), and SERS activity towards three various analytes. The unique geometry and wide spectral tunability of the CSLN substrates will also be of great value for other plasmon-driven applications.