Contents

Thickness-Resolved Plasmonic Windows in Graded Gold Nanoisland Films for Raman, Vapor, and Ellipsometric Sensing

Author(s): Fei Yu1, Chi Ming1
1University of Minnesota
Fei Yu
University of Minnesota
Chi Ming
University of Minnesota

Abstract

Gold nanoisland sensors are commonly optimized by following the largest optical response, although a single maximum does not define the best film for every readout. This paper determines how nominal Au thickness separates the functional windows of a graded, annealed gold nanoisland film used for Raman enhancement, ethanol transmission sensing, water-induced ellipsometric contrast, and ellipsometric detection of chemisorbed 4-mercaptobenzoic acid. The common coordinate is deposited Au thickness on fused silica. The decisive morphological transition occurs between 2.0 and 4.4 nm: particle density decreases from 2090 to 88 particles μm−2, while covered area decreases from 0.49 to 0.21. These numbers distinguish a junction-dense low-thickness state, an open-contact intermediate state, an oscillator-dominant high-thickness state, and a continuity-threshold state. 4-MBA Raman detection is strongest near 1.6 nm, where the 1074 and 1586 cm−1 bands are most intense under both 532 and 633 nm excitation. Ethanol sensing is strongest around 3.2–3.5 nm, and water-induced ellipsometric contrast occupies the broader 2.0–4.0 nm interval. Bound 4-MBA ellipsometry shifts to 6.8–7.0 nm, where the far-field response is stronger. The practical answer is therefore readout-specific: 1.4–2.2 nm for Raman, 2.8–3.6 nm for volatile or condensable analytes, 6.5–7.1 nm for bound-layer ellipsometry, and 2.0–3.5 nm as the best multimodal compromise.

Keywords: analytical spectroscopy; gold nanoislands; localized surface plasmon resonance; surface-enhanced Raman spectroscopy; spectroscopic ellipsometry; vapor sensing; water adsorption; sensor selection
Copyright © 2025 Fei Yu, Chi Ming. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.