Accurate results from perturbation theory for strongly frustrated S=1/2 Heisenberg spin clusters - art. no. 184436

We investigate the use of perturbation theory in finite-sized frustrated sp in systems by calculating the effect of quantum fluctuations on coherent st ates derived from the classical ground state. We first calculate the ground - and first-excited-state wave functions as a function of applied field for a 12-site system and compare with the results of exact diagonalization. We then apply the technique to a 20-site system with the same threefold site coordination as the 12-site system. Frustration results in asymptotically c onvergent series for both systems which are summed with Pade approximants. We find that at zero magnetic field the different connectivity of the two s ystems leads to a triplet first excited state in the 12-site system and a s inglet first excited state in the 20-site system, while the ground state is a singlet for both. We also show how the analytic structure of the Pade ap proximants at \lambda\ similar or equal to 1 evolves in the complex lambda plane at the values of the applied field where the ground state switches be tween spin sectors and how this is connected with the nontrivial dependence of the [S-z] number on the strength of quantum fluctuations. We discuss th e origin of this difference in the energy spectra and in the analytic struc tures. We also characterize the ground and first excited states according t o the values of the various spin correlation functions.