Insights into the excited state dynamics of Fe(ii) polypyridyl complexes from variable-temperature ultrafast spectroscopy.

In an effort to better define the nature of the nuclear coordinate associated with excited state dynamics in first-row transition metal-based chromophores, variable-temperature ultrafast time-resolved absorption spectroscopy has been used to determine activation parameters associated with ground state recovery dynamics in a series of low-spin Fe(ii) polypyridyl complexes. Our results establish that high-spin (5 T2 ) to low-spin (1 A1 ) conversion in complexes of the form [Fe(4,4'-di-R-2,2'-bpy')3 ]2+ (R = H, CH3 , or tert -butyl) is characterized by a small but nevertheless non-zero barrier in the range of 300-350 cm-1 in fluid CH3 CN solution, a value that more than doubles to ∼750 cm-1 for [Fe(terpy)2 ]2+ (terpy = 2,2':6',2''-terpyridine). The data were analyzed in the context of semi-classical Marcus theory. Changes in the ratio of the electronic coupling to reorganization energy (specifically, H ab 4 / λ ) reveal an approximately two-fold difference between the [Fe(bpy')3 ]2+ complexes (∼1/30) and [Fe(terpy)2 ]2+ (∼1/14), suggesting a change in the nature of the nuclear coordinate associated with ground state recovery between these two types of complexes. These experimentally-determined ratios, along with estimates for the 5 T2 /1 A1 energy gap, yield electronic coupling values between these two states for the [Fe(bpy')3 ]2+ series and [Fe(terpy)2 ]2+ of 4.3 ± 0.3 cm-1 and 6 ± 1 cm-1 , respectively, values that are qualitatively consistent with the second-order nature of high-spin/low-spin coupling in a d6 ion. In addition to providing useful quantitative information on these prototypical Fe(ii) complexes, these results underscore the utility of variable-temperature spectroscopic measurements for characterizing ultrafast excited state dynamics in this class of compounds.