Dynamic inhomogeneity, pairing and superconductivity in cuprates

TL;DR

This review discusses experimental and theoretical evidence for dynamic inhomogeneity, pairing, and stripe formation in cuprate superconductors, highlighting their role in the emergence of superconductivity.

Contribution

It provides a comprehensive synthesis of experimental data and theoretical models linking dynamic inhomogeneity, bipolaron pairing, and stripe phenomena to high-temperature superconductivity in cuprates.

Findings

Experimental evidence for dynamic inhomogeneity at various scales.

Theoretical models linking electron, spin, and lattice interactions to pairing.

Superconductivity arises from phase coherence percolation across pairs and stripes.

Abstract

In this review we examine the experimental evidence for dynamic inhomogeneity, defining the length, time and energy scales of the relevant elementary excitations. The dynamics of the objects below and above Tc are examined in detail with femtosecond spectroscopy and compared with magnetic and other measurements. The dynamically inhomogeneous state is described theoretically by considering an interaction between electrons, spins and the lattice. By symmetry, only electrons in degenerate states can couple to the lattice and spins to give an anisotropic, d-wave symmetry interaction. The proposed interaction acts on a mesoscopic length-scale, taking into account the interplay of Coulomb repulsion between particles and anisotropic elastic strain, and leads to the formation of bipolaron pairs and stripes. The predicted symmetry breaking associated with pairing and stripe formation are observed in numerous experiments. The phenomenology associated with the co-existence of pairs and clusters (stripes) is found to apply to many different experiments ranging from femtosecond dynamics to transport measurements. Excitations of the system are described quite well in terms of a 2-level system, although we find that a complete description may require a more complicated energy landscape due to presence of mesoscopic objects such as stripes or clusters. The formation of the superconducting state can be understood quantitatively to be the result of the establishment of phase coherence percolation across pairs and stripes.