Abstract
In [Fe-Fe] hydrogenase mimic systems the ene-1,2-dithiolene ligands play an important role in the stabilisation of the redox-active metal center. This is demonstrated by the benzenedithiolene (bdt) analogue, featuring six terminal carbonyl ligands connected to a di-iron metal center, i.e. [Fe2(bdt)(CO)6]. Here we present a combined experimental and theoretical study that elucidates key intermediates [Fe2(bdt)(CO)6]1- and [Fe2(bdt)(μ-CO)(CO)5]2- in the electrocatalytic production of dihydrogen. A DFT study shows that [Fe2(bdt)(CO)6]1- is the kinetic product after the first one electron reduction, while the previously proposed bridging intermediate species [Fe2(bdt)(μ-CO)(CO)5]1- is kinetically inaccessible. The doubly reduced species [Fe2(bdt)(μ-CO)(CO)5]2- was for the first time structurally characterized using EXAFS. XANES analysis confirms the existence of reduced iron zero species and confirms the distorted geometry that was suggested by the DFT calculations. Combining IR, UV-vis and XAS spectroscopic results with TD-DFT and FEFF calculations enabled us to assign the key-intermediate [Fe2(bdt)(CO)6]2-. This study emphasizes the strengths of combining computational chemistry with advanced spectroscopy techniques.
Highlights
The ever-increasing demand to replace our current fossil fueldriven economy by sustainable alternatives has intensified the research field on alternative energy sources
XANES analysis confirms the existence of reduced iron zero species and confirms the distorted geometry that was suggested by the DFT calculations
We have investigated the reduction of hydrogenase mimic [Fe2(bdt)(CO)6] with a combined X-ray absorption spectroscopy (XAS)-DFT study, revealing the structural rearrangement of the catalyst after the second electron reduction
Summary
The ever-increasing demand to replace our current fossil fueldriven economy by sustainable alternatives has intensified the research field on alternative energy sources. Water splitting using green energy would be sustainable, but for proton reduction catalysis the best catalysts are still based on non-abundant metals like platinum.. Many simple bio-mimetic analogues have been synthesised and characterised over the past decades. To characterize these systems, many techniques like, cyclic a Sustainable Materials Characterization, van’t Hoff Institute for Molecular Sciences, University of Amsterdam, Science Park 904, 1098 XH Amsterdam, The Netherlands b Homogeneous, Supramolecular and Bio-Inspired Catalysis, van’t Hoff Institute for Molecular Sciences, University of Amsterdam, Science Park 904, 1098 XH Amsterdam, The Netherlands.
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