Universality of transition temperatures in families of copper-oxide superconductors: interlayer tunneling redux

TL;DR

This paper revisits the interlayer tunneling theory to explain the consistent transition temperatures in copper-oxide superconductors, considering competing orders and charge imbalance, with results aligning well with experiments.

Contribution

It extends the interlayer tunneling theory by incorporating competing order parameters and charge imbalance effects, providing a comprehensive explanation for the observed systematics of transition temperatures.

Findings

Theoretical results match experimental transition temperature trends.

Charge imbalance influences superconducting properties.

Competing orders suppress or enhance superconductivity as predicted.

Abstract

We revisit the interlayer tunneling theory of high temperature superconductors and formulate it as a mechanism by which the striking systematics of the transition temperature within a given homologous series can be understood. We pay attention not only to the enhancement of pairing, as was originally suggested, but also to the role of competing order parameters that tend to suppress superconductivity, and to the charge imbalance between inequivalent outer and inner CuO2 planes in a unit cell. Calculations based on a generalized Ginzburg-Landau theory yield results that bear robust and remarkable resemblance to experimental observations.