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Dissecting the Triplet-State Properties and Intersystem Crossing Mechanism of the Ligand-Protected Au<sub>13</sub> Superatom

Kouta Yoshida, Daichi Arima, Masaaki Mitsui

2023The Journal of Physical Chemistry Letters28 citationsDOI

Abstract

Icosahedral Au 13 nanoclusters are among the most typical superatoms and are of great interest as promising building blocks for nanocluster-assembled materials. Herein, the key parameters involved in the intersystem crossing (ISC) process of [Au 13 (dppe) 5 Cl 2 ] 3+ ( Au 13; dppe = 1,2-bis(diphenylphosphino)ethane) were characterized. Quenching experiments using aromatic compounds revealed that the T 1 energy of Au 13 is 1.63 eV. An integrative interpretation of our experimental results and the relevant literature uncovered important facts concerning the Au 13 superatom: the ISC quantum yield is unity due to the ultrafast ISC (∼10 12 s –1 ), the lowest absorption band includes contributions of direct singlet–triplet transitions, and there exists a large S 1 –T 1 gap of 0.73 eV. To explain the efficient ISC, the El-Sayed rule was applied to the superatomic orbitals corresponding to the excited-state hole/electron distributions obtained from theoretical calculations. The strong spin–orbit coupling between the S 1 and T 2 –T 4 states offers a reasonable explanation for the ultrafast ISC.

Topics & Concepts

Intersystem crossingSuperatomChemistryNanoclustersSinglet stateTriplet stateExcited stateChemical physicsAtomic physicsComputational chemistryElectronic structurePhysicsOrganic chemistryNanocluster Synthesis and ApplicationsAdvanced Nanomaterials in CatalysisPharmacological Effects and Toxicity Studies
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