Abstract

Light-induced excited spin state trapping (LIESST) in Fe^II spin-crossover systems is a process that involves the switching of molecules from low (LS, <i>S</i> = 0) to high spin (HS, <i>S</i> = 2) states. The direct LS-to-HS conversion is forbidden by selection rules, and LIESST involves intermediate states such as ^1,3MLCT or ^1,3T. The intersystem crossing sequence results in an HS state, structurally trapped by metal-ligand bond elongation through the coherent activation and damping of molecular breathing. The ultrafast dynamics of this process has been investigated in FeN₆ ligand field systems, under MLCT excitation. Herein, we studied LIESST in an Fe^IIN₄O₂ spin-crossover material of lower symmetry, which allowed for quite intense and low-energy shifted d-d bands. By combining <i>ab initio</i> DFT and TD-DFT calculations and fs optical absorption measurements, we demonstrated that shorter intermediates enhanced coherent structural dynamics, and d-d excitation induced faster LS-to-HS switching, compared to MLCT.