posted on 2024-04-08, 13:04authored byCasey Van Stappen, Benjamin E. Van Kuiken, Max Mörtel, Kari O. Ruotsalainen, Dimitrios Maganas, Marat M. Khusniyarov, Serena DeBeer
The molecular spin-crossover
phenomenon between high-spin
(HS)
and low-spin (LS) states is a promising route to next-generation information
storage, sensing applications, and molecular spintronics. Spin-crossover
complexes also provide a unique opportunity to study the ligand field
(LF) properties of a system in both HS and LS states while maintaining
the same ligand environment. Presently, we employ complementing valence
and core-level spectroscopic methods to probe the electronic excited-state
manifolds of the spin-crossover complex [FeII(H2B(pz)2)2phen]0. Light-induced excited
spin-state trapping (LIESST) at liquid He temperatures is exploited
to characterize magnetic and spectroscopic properties of the photoinduced
HS state using SQUID magnetometry and magnetic circular dichroism
spectroscopy. In parallel, Fe 2p3d RIXS spectroscopy is employed to
examine the ΔS = 0, 1 excited LF states. These
experimental studies are combined with state-of-the-art CASSCF/NEVPT2
and CASCI/NEVPT2 calculations characterizing the ground and LF excited
states. Analysis of the acquired LF information further supports the
notion that the spin-crossover of [FeII(H2B(pz)2)2phen]0 is asymmetric, evidenced by
a decrease in eπ in the LS state. The results demonstrate
the power of cross-correlating spectroscopic techniques with high
and low LF information content to make accurate excited-state assignments,
as well as the current capabilities of ab initio theory in interpreting
these electronic properties.