A Theory for High-Tc Superconductors Considering Inhomogeneous Charge Distribution
Abstract
We propose a general theory for the critical Tc and pseudogap T* temperature dependence on the doping concentration for high-Tc oxides, taking into account the charge inhomogeneities in the CuO2 planes. The well measured experimental inhomogeneous charge density in a given compound is assumed to produce a spatial distribution of local (r). These differences in the local charge concentration is assumed to yield insulator and metallic regions, possibly in a stripe morphology. In the metallic region, the inhomogeneous charge density yields also spatial distributions of superconducting critical temperatures Tc(r) and zero temperature gap 0(r). For a given sample, the measured onset of vanishing gap temperature is identified as the pseudogap temperature, that is, T*, which is the maximum of all Tc(r). Below T*, due to the distribution of Tc(r)'s, there are some superconducting regions surrounded by insulator or metallic medium. The transition to a superconducting state corresponds to the percolation threshold among the superconducting regions with different Tc(r)'s. To model the charge inhomogeneities we use a double branched Poisson-Gaussian distribution. To make definite calculations and compare with the experimental results, we derive phase diagrams for the BSCO, LSCO and YBCO families, with a mean field theory for superconductivity using an extended Hubbard Hamiltonian. We show also that this novel approach provides new insights on several experimental features of high-Tc oxides.
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