Using a newly developed first-principles Wannier-states approach that takes
into account large on-site Coulomb repulsion, we derive the effective
low-energy interacting Hamiltonians for several prototypical high-Tcβ
superconducting cuprates. The material dependence is found to originate
primarily from the different energy of the apical atom pzβ state.
Specifically, the general properties of the low-energy hole state, namely the
Zhang-Rice singlet, are significantly modified by a triplet state associated
with this pzβ state, via additional intra-sublattice hoppings,
nearest-neighbor "super-repulsion", and other microscopic many-body processes.
Possible implications on modulation of Tcβ, local superconducting gaps,
charge distribution, hole mobility, electron-phonon interaction, and
multi-layer effects are discussed.Comment: 5 pages, 3 figures, 1 tabl