High Spin Mn Molecular Clusters: Spin State Effects on the Outer Core-Level Multiplet Structures
Abstract
Oxo-bridged manganese polynuclear complexes have applications in a variety of technologies, such as single-molecule nanomagnets, catalysis and photosynthetic redox chemistry. The reason that these types of compounds are capable of such important and varied technologies is thought to be because they possess ground states with large spin values. However, the electronic, structural and magnetochemical relationships are not well understood and need to be thoroughly investigated to adequately explain why Mn is such an integral part of so many useful processes. X-ray photoemission spectroscopy was used to study the Mn 3p, 3s and valence band electronic behavior as a function of Mn cluster structural properties, where the cluster size and nuclearity are systematically varied. Results show a chemical shift of the Mn 3p(3/2,1/2) spin-orbit pair related to the cluster size and nuclearity. Also, the Mn 3s S-7 and S-5 final state multiplet components shift since it involves the binding energy of a ligand valence electron. In addition, the branching ratio of the S-7 S-5 states is related to the 3s-3d electron correlation. Specifically, in the S-7 state, the remaining 3s electron is well correlated with the 3d electrons of parallel spin, while in the S-5 state the two spins are antiparallel. Changes in this electron correlation are clearly observed in the S-7:S-5 branching ratio as a function of cluster size and ligand electronegativity.
Document Details
- Document Type
- Technical Report
- Publication Date
- Jan 01, 2001
- Accession Number
- ADP011019
Entities
People
- A. J. Nelson
- George Christou
- J. G. Reynolds
Organizations
- Lawrence Livermore National Laboratory