Toward a topological scenario for high-temperature superconductivity of copper oxides

Abstract

The structure of the joint phase diagram demonstrating high-Tc superconductivity of copper oxides is studied on the basis of the theory of interaction-induced flat bands. Prerequisites of an associated topological rearrangement of the Landau state are established, and related non-Fermi-liquid (NFL) behavior of the normal states of cuprates is investigated. We focus on manifestations of this behavior in the electrical resistivity (T), especially the observed gradual crossover from normal-state T-linear behavior (T,x)=A1(x)T at doping x below the critical value xch for termination of superconductivity, to T-quadratic behavior at x>xch, which is incompatible with predictions of the conventional quantum-critical-point scenario. It is demonstrated that at x<xhc, in agreement with available experimental data, the coefficient A1( x) is decomposed into the product of two factors, one of which changes linearly with doping x, while the second is universal, being of the Planckian form.