Spin‐Controlled Binding of Carbon Dioxide by an Iron Center: Insights from Ultrafast Mid‐Infrared Spectroscopy

The influence of the spin on the mode of binding between carbon dioxide (CO2) and a transition‐metal (TM) center is an entirely open question. Herein, we use an iron(III) oxalato complex with nearly vanishing doublet–sextet gap, and its ultrafast photolysis, to generate TM‐CO2 bonding patterns and determine their structure in situ by femtosecond mid‐infrared spectroscopy. The formation of the nascent TM‐CO2 species according to [L4FeIII(C2O4)]+ + hν → [L4Fe(CO2)]+ + CO2, with L4=cyclam, is evidenced by the coincident appearance of the characteristic asymmetric stretching absorption of the CO2‐ligand between 1600 cm−1 and 1800 cm−1 and that of the free CO2‐co‐fragment near 2337 cm−1. On the high‐spin surface (S=5/2), the product complex features a bent carbon dioxide radical anion ligand that is O‐“end‐on”‐bound to the metal. In contrast, on the intermediate‐spin and low‐spin surfaces, the product exhibits a “side‐on”‐bound, bent carbon dioxide ligand that has either a partial open‐shell (for S=3/2) or fully closed‐shell character (for S=1/2). Snapshots from femtosecond mid‐infrared laser spectroscopy reveal spin‐dependent formation of different binding modes of carbon dioxide to a transition‐metal center. The ultrafast excitation of an iron(III) oxalate precursor complex with ultraviolet pulses releases a neutral carbon dioxide molecule within 500 fs and generates a nascent iron‐CO2‐primary complex that isomerizes on a picosecond time scale.