Bright NIR-II Photoluminescence in Rod-Shaped Icosahedral Gold Nanoclusters

Fluorophores with high quantum yields, extended maximum emission wavelengths, and long photoluminescence (PL) lifetimes are still lacking for sensing and imaging applications in the second near-infrared window (NIR-II). In this work, a series of rod-shaped icosahedral nanoclusters with bright NIR-II PL, quantum yields up to approximate to 8%, and a peak emission wavelength of 1520 nm are reported. It is found that the bright NIR-II emission arises from a previously ignored state with near-zero oscillator strength in the ground-state geometry and the central Au atom in the nanoclusters suppresses the non-radiative transitions and enhances the overall PL efficiency. In addition, a framework is developed to analyze and relate the underlying transitions for the absorptions and the NIR-II emissions in the Au nanoclusters based on the experimentally defined absorption coefficient. Overall, this work not only shows good performance of the rod-shaped icosahedral series of Au nanoclusters as NIR-II fluorophores, but also unravels the fundamental electronic transitions and atomic-level structure-property relations for the enhancement of the NIR-II PL in gold nanoclusters. The framework developed here also provides a simple method to analyze the underlying electronic transitions in metal nanoclusters.

Automated summary

This study reports rod-shaped icosahedral nanoclusters with bright NIR-II PL, quantum yields up to approximately 8%, and a peak emission wavelength of 1520 nm. The central Au atom in the nanoclusters is found to enhance overall PL efficiency and make NIR-II emission brighter. A framework is developed to analyze underlying transitions in metal nanoclusters based on experimentally defined absorption coefficients.