Based on first-principles density-functional theory calculations we
investigate the electronic structure of hexanuclear "ferric wheels" M
Fe_6[N(CH_2 CH_2 O)_3]_6 Cl (M = Li, Na) in their antiferromagnetic ground
state. The electronic structure is presented in form of spin- and site-resolved
local densities of states. The latter clearly indicate that the magnetic moment
is distributed over several sites. The local moment at the iron site is still
the largest one with about 4 mu_B, thus indicating the valence state of iron to
be closer to Fe(II) than to commonly accepted Fe(III). The local spin of S=5/2
per iron site, following from magnetization measurements, is perfectly
reproduced if one takes the moments on the neighbor atoms into account. The
largest magnetic polarization is found on the apical oxygen atom, followed by
nitrogen bridging oxygens. These findings are confirmed by a map of spatial
spin density. A further goal of the present study has been a comparative test
of two different DFT implementations, Siesta and NRLMOL. They yield a very good
agreement down to small details in the electronic structure.Comment: 10 pages, 3 embedded postscript figures, to be published in Molecular
Physics Reports (proceedings of the Summer School on New Magnetics - Bedlewo,
Poland, September 2003). Two references update