Significantly enhanced NIR emission of solid-state clusters based on CuPt triggered with volatile organic compounds.

Near-infrared (NIR) emitting metal clusters, recognized for their low toxicity, large Stokes shift, and exceptional photostability, hold considerable promise as stimuli-responsive luminescent materials for applications including organic vapor sensing, pollutant detection, and photoluminescent thermometers. However, their limited quantum yield (QY) for NIR emission poses a challenge, highlighting the need for developing light-up sensors with NIR emitting metal clusters to broaden the scope of applications. Herein, the carbazole-alkyne ligand-incorporated novel bimetallic cluster, CuPt(CZ-PrA)(dppy)(PF) (CZ-Cu4Pt2, CZ-PrAH = 9-(Prop-2-yn-1-yl)-9-carbazole; dppy = diphenyl-2-pyridylphosphine), was synthesized, which exhibits NIR emission centered at 740 nm in the solid state and shows a significant blue shift compared to the previously reported analogues.

Highly intense NIR emissive CuPt bimetallic clusters featuring Pt(i)-Cu-Pt(i) sandwich kernel.

Metal nanoclusters (NCs) capable of near-infrared (NIR) photoluminescence (PL) are gaining increasing interest for their potential applications in bioimaging, cell labelling, and phototherapy. However, the limited quantum yield (QY) of NIR emission in metal NCs, especially those emitting beyond 800 nm, hinders their widespread applications. Herein, we present a bright NIR luminescence (PLQY up to 36.

Visible-Light-Driven NO Release from Postmodified MOFs via Photoinduced Electron Transfer for Antibacterial Application.

Photoresponsive nitric oxide (NO)-releasing materials (NORMs) enable the spatiotemporal delivery of NO to facilitate their potential applications in physiological conditions. Here two novel metal-organic frameworks (MOFs)-based photoactive NORMs achieved by the incorporation of prefunctionalized NO donors into the photosensitive Fe-MOFs via a postmodification strategy is reported. The modified Fe-MOFs display superior photoactivity of NO release when exposed to visible light (up to 720 nm).