Litcius/Paper detail

Insights into the excited-state behavior of metal nanoclusters: from structure-based properties to dynamic control via ionic association

Wataru Ishii, Takuya Nakashima

2025Bulletin of the Chemical Society of Japan7 citationsDOIOpen Access PDF

Abstract

Abstract Metal nanoclusters possess atomically precise structures and quantized electronic states, exhibiting optical properties derived from electronic transitions between orbitals with discrete energy levels. While the structural behaviors of nanoclusters in the ground state have been extensively studied, their excited-state dynamics remain elusive. The excited-state behavior of nanoclusters may include the relaxation pathways, structural change, and the spatial distribution of excitons. In this account, we first survey how heterometal substitution, surface structure, and environmental factors influence the excited-state relaxation pathways in structurally defined nanoclusters. We then highlight our recent discovery of how the dynamic interaction of counterions with the nanocluster surface has an effect on the properties of the excited state. This ionic interaction in the T1 state leads to changes in its energy, spatial localization, and chiroptical activity. This phenomenon, supported by time-resolved spectroscopy and quantum chemical calculations, represents an emerging strategy for controlling the excited-state nature of nanoclusters. By complementing conventional static design approaches, dynamic ion association could provide a powerful tool for designing photofunctional nanocluster materials.

Topics & Concepts

NanoclustersChemistryIonic bondingChemical physicsCounterionExcited stateAtomic orbitalRelaxation (psychology)SpectroscopyIonNanotechnologyGround stateMetalElectronic structureMolecular dynamicsPotential energy surfacePhotoemission spectroscopyQuantum chemicalComputational chemistryQuantumQuantum dotSmart materialElectrostaticsTransition metalNanocluster Synthesis and ApplicationsGold and Silver Nanoparticles Synthesis and ApplicationsSpectroscopy and Quantum Chemical Studies