Theory for the Interdependence of High-Tc Superconductivity and Dynamical Spin Fluctuations
Abstract
The doping dependence of the superconducting state for the 2D one-band Hubbard Hamiltonian is determined. By using an Eliashberg-type theory, we find that the gap function k has a dx2-y2 symmetry in momentum space and Tc becomes maximal for 13 \; \% doping. Since we determine the dynamical excitations directly from real frequency axis calculations, we obtain new structures in the angular resolved density of states related to the occurrence of shadow states below Tc. Explaining the anomalous behavior of photoemission and tunneling experiments in the cuprates, we find a strong interplay between d-wave superconductivity and dynamical spin fluctuations.
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