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Abstract
This study comprehensively investigates the excited-state dynamics of two tungsten iodide prototype clusters, [(W6I8)I6]2- and [(W6I8)(TFA)6]2- (TFA = trifluoroacetate) utilizing a combination of ultrafast transient absorption spectroscopy from 200 fs up to 400 µs and temperature-dependent emission spectroscopy from 4 to 340 K. Both clusters exhibit rapid intersystem crossing occurring within 6 picoseconds, populating triplet states that subsequently deactivate through emission or dynam-ical bimolecular quenching involving molecular oxygen. The temperature-dependent emission behavior aligns well with a group-theoretical spin sublevel model, indicating three distinct emissive sublevels. However, contrary to previous findings in molybdenum-based clusters, no additional splitting of the lowest triplet states was observed experimentally. Time-dependent density functional theory (TDDFT) calculations highlight substantial excited-state geometrical distortions, suggesting limita-tions in sole group-theoretical descriptions. Instead, we propose a relativistic model with three thermally accessible excited-state geometries, each presenting three triplet sublevels.
