Enhancing Single-Molecule Fluorescence Spectroscopy with Simple and Robust Hybrid Nanoapertures

Plasmonic nanoapertures have found exciting applications in optical sensing, spectroscopy, imaging, and nanomanipulation. The subdiffraction optical field localization, reduced detection volume (similar to attoliters), and background-free operation make them particularly attractive for single-particle and single-molecule studies. However, in contrast to the high field enhancements by traditional nanoantenna-based structures, small field enhancement in conventional nanoapertures results in weak light-matter interactions and thus small enhancement of spectroscopic signals (such as fluorescence and Raman signals) of the analytes interacting with the nanoapertures. In this work, we propose a hybrid nanoaperture design termed gold-nanoisland-sembedded nanoaperture (AuNIs-e-NA), which provides multiple electromagnetic hotspots within the nanoaperture to achieve field enhancements of up to 4000. The AuNIs-e-NA was able to improve the fluorescence signals by more than 2 orders of magnitude with respect to a conventional nanoaperture. With simple design and easy fabrication, along with strong signal enhancements and operability over variable light wavelengths and polarizations, the AuNIs-e-NA will serve as a robust platform for surface-enhanced optical sensing, imaging, and spectroscopy.

Automated summary

Plasmonic nanoapertures have various exciting applications, but traditional nanoapertures may result in weak light-matter interactions. A new hybrid nanoaperture design, AuNIs-e-NA, provides multiple electromagnetic hotspots and can achieve up to 4000-fold field enhancements, significantly improving fluorescence signals. With simple design, easy fabrication, and strong signal enhancements, AuNIs-e-NA is a robust platform for surface-enhanced optical sensing, imaging, and spectroscopy.