Abstract
Recently synthetized iron complexes have achieved long-lived excited states and stabilities which are comparable, or even superior, to their ruthenium analogues, thus representing an eco-friendly and cheaper alternative to those materials based on rare metals. Most of computational tools which could help unravel the origin of this large efficiency rely on ab-initio methods which are not able, however, to capture the nanosecond time scale underlying these photophysical processes and the influence of their realistic environment. Therefore, it exists an urgent need of developing new low-cost, but still accurate enough, computational methodologies capable to deal with the steady-state and transient spectroscopy of transition metal complexes in solution. Following this idea, here we focus on the comparison between general-purpose transferable force-fields (FFs), directly available from existing databases, and specific quantum mechanical derived FFs (QMD-FFs), obtained in this work through the Joyce procedure. We have chosen a recently reported FeIII complex with nanosecond excited-state lifetime as a representative case. Our molecular dynamics (MD) simulations demonstrated that the QMD-FF nicely reproduces the structure and the dynamics of the complex and its chemical environment within the same precision as higher cost QM methods, whereas general-purpose FFs failed in this purpose. Although in this particular case the chemical environment plays a minor role on the photo physics of this system, these results highlight the potential of QMD-FFs to rationalize photophysical phenomena provided an accurate QM method to derive its parameters is chosen.
Highlights
Photoactive transition metal complexes (TMCs) characterized by long-lived metal to ligand charge transfer (MLCT) excited states have found successful application in different technological fields, spanning from natural and artificial photosynthesis [1,2,3,4], photovoltaic applications [5,6,7,8] to light-assisted medical therapies [9,10,11]
Since we have shown that thermal and solvent effects have a negligible impact on the position of the (2 ligand-to metal charge-transfer (LMCT)) band, we can take the static density functional theory (DFT) spectrum in implicit solvent as a reference to estimate the deviation from the experimental results
The direct comparison between the experimental X-ray diffraction (XRD) patterns, the reference quantum mechanics (QM) ground state (GS) and the structures obtained by molecular mechanics (MM) energy minimizations with a quantum mechanical derived force fields (FF) (QMD-FFs) and a general purpose FF procedure is a clear indication of the need of including QM effects in the derivation of the FF parameters for a realistic description of the octahedral coordination around iron complexes
Summary
Photoactive transition metal complexes (TMCs) characterized by long-lived (hundreds of picoseconds up to nanoseconds) metal to ligand charge transfer (MLCT) excited states have found successful application in different technological fields, spanning from natural and artificial photosynthesis [1,2,3,4], photovoltaic applications [5,6,7,8] to light-assisted medical therapies [9,10,11]. Important breakthroughs in increasing the MLCT lifetime have been reported in the last years [28,29,30,31,32], spanning from tens of picoseconds [33,34,35,36] to the nanosecond time scale [37]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
