Dynamically screened Coulomb interaction in the parent compounds of hole-doped cuprates, trends and exceptions

Abstract

Although the cuprate high-temperature superconductors were discovered already 1986 the origin of the pairing mechanism remains elusive. While the doped compounds are superconducting with high transition temperatures Tc the undoped compounds are insulating due to the strong effective Coulomb interaction between the Cu 3d holes. We investigate the dependence of the maximum superconducting transition temperature, Tc max, on the onsite effective Coulomb interaction U using the constrained random-phase approximation. We focus on the commonly used one-band model of the cuprates, including only the antibonding combination of the Cu dx2-y2 and O px and py orbitals, and find a clear screening dependent trend between the static value of U and Tc max for the parent compounds of a large number of hole-doped cuprates. Our results suggest that superconductivity is favored by a large onsite Coulomb repulsion. We analyze both the trend in the static value of U and its frequency dependence in detail and, by comparing to other works, speculate on the mechanisms behind the trend.