Abstract
The relationship between electronic structure and zero-field splitting dictates key design parameters for magnetic molecules. In particular, to enable the directed synthesis of new electronic spin based qubits, developing complexes where zero-field splitting energies are invariant to structural changes is a critical challenge. Toward those ends, we report three salts of a new compound, a four-coordinate iron(ii) complex [Fe(C(3)S(5))(2)](2-) ([(18-crown-6)K](+) (1), Ph(4)P(+) (2), Bu(4)N(+) (3)) with a continuous structural variation in a single parameter, the dihedral angle (θ(d)) between the two C(3)S(5)(2-) ligands, as a function of counterion (θ(d) = 89.98(4)° for 1 to 72.41(2)° for 3). Electron paramagnetic resonance data for 1-3 reveal zero-field splitting parameters that are unusually robust to the structural variation. Mössbauer spectroscopic measurements indicate that the structural variation in θ(d) primarily affects the highest-energy 3d-orbitals (d (xz) and d (yz) ) of the iron(ii) ion. These orbitals have the smallest impact on the zero-field splitting parameters, thus the distortion has a minor effect on D and E. These results represent the first part of a directed effort to understand how spin state energies may be fortified against structural distortions for future applications of qubits in non-crystalline environments.