posted on 2024-07-11, 14:47authored byKamil Witas, Shruthi Santhosh Nair, Tamar Maisuradze, Linda Zedler, Heiner Schmidt, Pablo Garcia-Porta, Alexandra Stefanie Jessica Rein, Tim Bolter, Sven Rau, Stephan Kupfer, Benjamin Dietzek-Ivanšić, Dieter U. Sorsche
Molecular transition metal chromophores play a central role in
light harvesting and energy conversion. Recently, earth-abundant transition-metal-based
chromophores have begun to challenge the dominance of platinum group
metal complexes in this area. However, the development of new chromophores
with optimized photophysical properties is still limited by a lack
of synthetic methods, especially with respect to heteroleptic complexes
with functional ligands. Here, we demonstrate a facile and efficient
method for the combination of strong-field carbenes with the functional
2,2′-bibenzimidazole ligand in a heteroleptic iron(II) chromophore
complex. Our approach yields two isomers that differ predominantly
in their excited-state lifetimes based on the symmetry of the ligand
field. Deprotonation of both isomers leads to a significant red-shift
of the metal-to-ligand charge transfer (MLCT) absorption and a shortening
of excited-state lifetimes. Femtosecond transient absorption spectroscopy
in combination with quantum chemical simulations and resonance Raman
spectroscopy reveals the complex relationship between protonation
and photophysical properties. Protonation is found to tip the balance
between MLCT and metal-centered (MC) excited states in favor of the
former. This study showcases the first example of fine-tuning of the
excited-state landscape in an iron(II) chromophore through second-sphere
manipulations and provides a new perspective to the challenge of excited-state
optimizations in 3d transition metal chromophores.