We show that reducing the crystal size of [Mn12 O12 (O2 C6 H5) 16 (H2 O) 4] single-molecule magnets from 11.5 to 0.4 μm strongly affects the molecular magnetic anisotropy and magnetic-relaxation rates. The effective activation energy for the spin reversal of the standard clusters decreases by 13% with decreasing size, whereas it remains approximately constant for the "fast relaxing" species. The pre-exponential factor τ0 increases with decreasing crystal size for both. The observed decrease in the effective energy barrier for the slow relaxing species seems to be associated with the existence of a distribution of second-order transverse anisotropy terms, centered on E=0, which broadens as the crystal size decreases. By contrast, the expected changes in the axial anisotropy parameter D with decreasing crystal size are too small to account for the change in U. The different effects that the reduction in crystal size has on the fast and slow relaxing species are discussed. © 2009 The American Physical Society.
|Journal||Physical Review B - Condensed Matter and Materials Physics|
|Publication status||Published - 5 Jun 2009|