Rational Design of a Confacial Pentaoctahedron: Anisotropic Exchange in a 
Linear ZnIIFeIIIFeIIIFeIIIZnII Complex

Walleck, Stephan; Atanasov, Mihail; Schnack, Jürgen; Bill, Eckhard; Stammler, Anja; Bögge, Hartmut; Glaser, Thorsten

doi:10.1002/chem.202102572

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Rational Design of a Confacial Pentaoctahedron: Anisotropic Exchange in a Linear Zn^IIFe^IIIFe^IIIFe^IIIZn^II Complex

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Atanasov, Mihail
Research Group Atanasov, Max-Planck-Institut für Kohlenforschung, Max Planck Society;
Institute of General and Inorganic Chemistry, Bulgarian Academy of Sciences;

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Citation

Walleck, S., Atanasov, M., Schnack, J., Bill, E., Stammler, A., Bögge, H., et al. (2021). Rational Design of a Confacial Pentaoctahedron: Anisotropic Exchange in a Linear Zn^IIFe^IIIFe^IIIFe^IIIZn^II Complex. Chemistry – A European Journal, 27(61), 15240-15251. doi:10.1002/chem.202102572.

Cite as: https://hdl.handle.net/21.11116/0000-0009-78A6-5

Abstract

The first confacial pentaoctahedron comprised of transition metal ions namely Zn^IIFe^III_AFe^III_BFe^III_AZn^II has been synthesized by using a dinucleating nonadentate ligand. The face-sharing bridging mode enforces short Zn^II⋅⋅⋅Fe^III_A and Fe^III_A⋅⋅⋅Fe^III_B distances of 2.83 and 2.72 Å, respectively. Ab-initio CASSCF/NEVPT2 calculations provide significant negative zero-field splittings for Fe^III_A and Fe^III_B with |D_A|>|D_B| with the main component along the C₃ axis. Hence, a spin-Hamiltonian comprised of anisotropic exchange, zero-field, and Zeeman term was employed. This allowed by following the boundary conditions from the theoretical results the simulation in a theory-guided parameter determination with J^xy=+0.37, J^z=−0.32, D_A=−1.21, E_A=−0.24, D_B=−0.35, and E_B=−0.01 cm⁻¹ supported by simulations of high-field magnetic Mössbauer spectra recorded at 2 K. The weak but ferromagnetic Fe^III_AFe^III_B interaction arises from the small bridging angle of 84.8° being at the switch from anti- to ferromagnetic for the face-sharing bridging mode.