Triggering Photoluminescence in High-Nuclear Silver Nanoclusters via Extra Silver Atom Incorporation

Photoluminescence (PL) in silver (Ag) nanoclusters (NCs) is intrinsically linked to their structural architecture, yet their low quantum yield at room-temperature hinders practical applications. Although various strategies have been explored to enhance the PL efficiency of Ag NCs, their effectiveness in high-nuclear Ag NCs remains largely uncertain. Here, we demonstrate a 77-fold enhancement in room-temperature PL quantum yield by modulating both radiative and non-radiative decay pathways in high-nuclear Ag NCs. A comparative study of two anion-templated Ag NCs, differing by a single Ag atom in the outermost shell, reveals that this substitution lowers structural symmetry, thereby increasing the radiative decay rate. This structural modification is facilitated by the alterations in ligands and their coordination environment, which simultaneously suppress atomic fluctuations and reduce the non-radiative decay component. Furthermore, theoretical investigations corroborate these findings, indicating that the incorporation of an additional Ag atom modifies the electronic distribution, thereby influencing the PL characteristics and ultimately al-tering the emission mechanism. These insights provide a deeper understanding of the structure–property relation-ship in high-nuclear Ag NCs and offer a rational strategy for enhancing their luminescence efficiency for potential applications.