The development of active, robust
systems for light-driven hydrogen
production from aqueous protons based on catalysts and light absorbers
composed solely of earth abundant elements remains a challenge in
the development of an artificial photosynthetic system for water splitting.
Herein, we report the synthesis and characterization of four closely
related Fe bis(benzenedithiolate) complexes that exhibit catalytic
activity for hydrogen evolution when employed in systems with water-soluble
CdSe QDs as photosensitizer and ascorbic acid as a sacrificial electron
source under visible light irradiation (520 nm). The complex with
the most electron-donating dithiolene ligand exhibits the highest
activity, the overall order of activity correlating with the reduction
potential of the formally Fe(III) dimeric dianions. Detailed studies
of the effect of different capping agents and the extent of surface
coverage of these capping agents on the CdSe QD surfaces reveal that
they affect system activity and provide insight into the continued
development of such systems containing QD light absorbers and molecular
catalysts for H<sub>2</sub> formation
