A real-space effective c-axis lattice constant theory of superconductivity

Abstract

Based on the recent developed real-space picture of superconductivity, we study the stability of the superconducting vortex lattices in layered superconductors. It is shown that the effective c-axis lattice constant play a significant role in promoting the superconducting transition temperature in these materials. An unified expression Tc(max)=10c*-28 can be applied to estimate the highest possible Tc(max) for a given layered superconductor with an effective c-axis lattice constant c*. For the newly discovered iron-based superconductors, our results suggest that their Tc cannot exceed 60K, 50K and 40K for the 1111, 21311 and 122 series, respectively. In the case of copper-based oxide superconductors, it seems that the highest Tc can reach about 161K without applying of the external pressure. In our theoretical framework, we could interpret the experimental results of the completely different superconducting transition temperatures obtained in two very similar cuprate superconductors (La2-xBaxCuO4 of 40K and Sr2-xBaxCuO3+δ of 98K). In addition, the physical reason why the superconductivity does not occur in noble metals (like gold, silver and copper) is discussed. Finally, we argue that the metallic hydrogen cannot exhibit superconductivity at room temperature, it even cannot be a superconductor at any low temperature.