A 9 ps (3)MLCT lifetime was achieved by a Fe(II) complex based on C(NHC)^N(py)^C(NHC) pincer ligands. This is the longest known so far for any kind of complexes of this abundant metal, and increased by almost two orders of magnitude compared to the reference Fe(II) bis-terpyridine complex.
Ultrafast photoinduced electron transfer preceding energy equilibration still poses many experimental and conceptual challenges to the optimization of photoconversion since an atomic-scale description has so far been beyond reach. Here we combine femtosecond transient optical absorption spectroscopy with ultrafast X-ray emission spectroscopy and diffuse X-ray scattering at the SACLA facility to track the non-equilibrated electronic and structural dynamics within a bimetallic donor-acceptor complex that contains an optically dark centre. Exploiting the 100-fold increase in temporal resolution as compared with storage ring facilities, these measurements constitute the first X-ray-based visualization of a non-equilibrated intramolecular electron transfer process over large interatomic distances. Experimental and theoretical results establish that mediation through electronically excited molecular states is a key mechanistic feature. The present study demonstrates the extensive potential of femtosecond X-ray techniques as diagnostics of non-adiabatic electron transfer processes in synthetic and biological systems, and some directions for future studies, are outlined.
Building a detailed understanding of the structure−function relationship is a crucial step in the optimization of molecular photocatalysts employed in water splitting schemes. The optically dark nature of their active sites usually prevents a complete mapping of the photoinduced dynamics. In this work, transient X-ray absorption spectroscopy highlights the electronic and geometric changes that affect such a center in a bimetallic model complex. Upon selective excitation of the ruthenium chromophore, the cobalt moiety is reduced through intramolecular electron transfer and undergoes a spin flip accompanied by an average bond elongation of 0.20 ± 0.03 Å. The analysis is supported by simulations based on density functional theory structures (B3LYP*/TZVP) and FEFF 9.0 multiple scattering calculations. More generally, these results exemplify the large potential of the technique for tracking elusive intermediates that impart unique functionalities in photochemical devices.
In-situ synchrotron radiation powder X-ray diffraction (SR-PXD) technique is a powerful tool to gain a deeper understanding of reaction mechanisms in crystalline materials. In this paper, the implementation of a new in-situ SR-PXD cell for solid-gas reactions is described in detail. The cell allows performing measurements in a range of pressure which goes from light vacuum (10-2 bar) up to 200 bar and temperatures from room temperature up to 550°C. The high precision, with which pressure and temperature are measured, enables to estimate the thermodynamic properties of the observed changes in the crystal structure and phase transformations.
Characterizing
structural distortions in the metastable spin states
of d4–d7 transition metal ion complexes
is crucial to understand the nature of their bistability and eventually
control their switching dynamics. In particular, the impact of the
Jahn–Teller effect needs to be assessed for any electronic
configuration that could be effectively degenerate, as in e.g. the
high-spin (HS) manifold of highly symmetric homoleptic FeII complexes. However, capturing its manifestations remains challenging
since crystallization generally alters the molecular conformations
and their interconversion. With the rapid progress of ultrafast X-ray
absorption spectroscopy, it is now possible to collect data with unprecedented
signal-to-noise ratio, opening up for detailed structural characterization
of transient species in the homogeneous solution phase. By combining
the analysis of picosecond X-ray absorption spectra with DFT simulations,
the structure of the photoinduced HS state is elucidated for solvated
[Fe(terpy)2]2+ (terpy = 2,2′:6′,2″-terpyridine).
This species can be viewed as the average 5B structure
in D
2 symmetry that originates from a
dynamic Jahn–Teller effect in the HS manifold. These results
evidence the active role played by this particular instance of vibronic
coupling in the formation of the HS state for this benchmark molecule.
Ultimately, correlating the interplay between intramolecular and intermolecular
degrees of freedom to conformational strain and distortions in real
time should contribute to the development of advanced functionalities
in transition metal ion complexes.
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