Synergistic coordination of diphosphine with primary and tertiary phosphorus centers: Ultrastable icosidodecahedral Ag30 nanoclusters with metallic aromaticity

Sci Adv. 2024 Nov 29;10(48):eads0728. doi: 10.1126/sciadv.ads0728. Epub 2024 Nov 27.

Abstract

As versatile ligands with extraordinary coordination capabilities, RPH2 (R = alkyl or aryl) are rarely used in constructing metal nanoclusters due to their volatility, toxicity, spontaneous flammability, and susceptibility to oxidation. In this work, we designed a primary and tertiary phosphorus-bound diphosphine chelator (2-Ph2PC6H4PH2) to create ultrastable silver nanoclusters with metallic aromaticity. By controlling the deprotonation rate of 2-Ph2PC6H4PH2 and adjusting the templates, we successfully synthesized two near-infrared emissive nanoclusters, Ag30 and Ag32, which have analogous icosidodecahedral Ag30 shells with an Ih symmetry. Deprotonated ligand (2-Ph2PαC6H4Pβ2-) exhibits a coordination mode of μ51(Pβ),η2(Pα,Pβ), which endows a unique metallic aromaticity to Ag30 and Ag32. The solution-processed organic light-emitting diodes based on Ag30 achieve an external quantum efficiency of 15.1%, representing the breakthrough in application of silver nanoclusters to near-infrared-emitting devices. This work represents a special ligand system for synthesizing ligand-protected coinage metal nanoclusters and opens up horizons of creating nanoclusters with distinct geometries and metal aromaticity.