Femtosecond X-ray Spectroscopy Directly Quantifies Transient Excited-State Mixed Valency.
Chelsea Liekhus-SchmaltzZachary W FoxAmity AndersenKasper S KjaerRoberto Alonso-MoriElisa BiasinJulia CarlstadMatthieu CholletJames D GaynorJames M GlowniaKiryong HongThomas KrollJae Hyuk LeeBenjamin I PoulterMarco ReinhardDimosthenis SokarasYu ZhangGilles DoumyAnne-Marie MarchStephen H SouthworthShaul MukamelAmy A CordonesRobert W SchoenleinNiranjan GovindMunira KhalilPublished in: The journal of physical chemistry letters (2022)
Quantifying charge delocalization associated with short-lived photoexcited states of molecular complexes in solution remains experimentally challenging, requiring local element specific femtosecond experimental probes of time-evolving electron transfer. In this study, we quantify the evolving valence hole charge distribution in the photoexcited charge transfer state of a prototypical mixed valence bimetallic iron-ruthenium complex, [(CN) 5 Fe II CNRu III (NH 3 ) 5 ] - , in water by combining femtosecond X-ray spectroscopy measurements with time-dependent density functional theory calculations of the excited-state dynamics. We estimate the valence hole charge that accumulated at the Fe atom to be 0.6 ± 0.2, resulting from excited-state metal-to-metal charge transfer, on an ∼60 fs time scale. Our combined experimental and computational approach provides a spectroscopic ruler for quantifying excited-state valency in solvated complexes.
Keyphrases
- density functional theory
- solar cells
- electron transfer
- high resolution
- molecular dynamics
- single molecule
- perovskite solar cells
- metal organic framework
- solid state
- dual energy
- small molecule
- molecular docking
- living cells
- lymph node metastasis
- magnetic resonance
- computed tomography
- room temperature
- molecular dynamics simulations
- cerebral ischemia
- magnetic resonance imaging
- electron microscopy
- nucleic acid