Single-ion and exchange anisotropy in high-symmetry tetramer single molecule magnets
Abstract
For equal-spin s1 tetramer single molecule magnets with ionic point groups g=Td, D4h, D2d, C4h, C4v, and S4, we write the group-invariant single-ion, Dzaloshinskii-Moriya, and symmetric anisotropic near-neighbor and next-nearest-neighbor exchange Hamiltonians using the respective local axial and azimuthal vector groups. The anisotropic exchange renormalized near-neighbor and next-nearest-neighbor isotropic exchange interactions are Jg and Jg'. Using our exact, compact forms for the single-ion matrix elements, we evaluate the eigenstates of the full Hamiltonian to first order in the various interactions. There are two types of ferromagnetic (FM) and antiferromagnetic (AFM) tetramers. In Type I, Jg'-Jg>0, the tetramers act as two dimers with the maximal pair quantum numbers s13=s24=2s1 at low temperature. Type II tetramers with Jg'-Jg<0 are frustrated, with minimal values of the pair quantum numbers s13 and s24 at low temperature. For both Type I and Type II AFM tetramers, we evaluate the first-order level-crossing inductions analytically for arbitary s1, and illustrate the results for s1=1/2, 1, 3/2. Accurate Hartree expressions for the thermodynamics, electron paramagnetic resonance (EPR) absorption and inelastic neutron scattering cross-section are given. A procedure to extract the effective microscopic parameters for Types I and II tetramers using EPR is given.
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