Superconductivity Without Pairing?

TL;DR

This paper proposes a new model of superconductivity based on charge-density waves and lattice distortions, challenging the traditional pairing paradigm and explaining flux quantization without electron pairing.

Contribution

It introduces a novel superconductivity mechanism involving charge-density waves and lattice distortions, diverging from the conventional electron pairing theory.

Findings

Predicts flux quantization without electron pairs

Describes a mobile superconducting state linked to charge-density waves

Suggests observable differences from BCS theory at microscopic scales

Abstract

Electron pairing is central to modern concepts of superconductivity, and provides a basis for the ubiquitous presence of h/2e in the theory and phenomenology. However, the lack of a consistent real-space picture of phonon-mediated pairing suggests that the pairing interpretation may be incomplete or even misleading. Alternatively, the present picture refers back to an old proposal by Frohlich, whereby superconductivity is based on an induced electron charge density wave coupled to a one-dimensional static lattice distortion. In the new picture, dynamic three-dimensional charge-density waves couple to coherent standing-wave phonons, giving rise to a mobile superconducting ground state that does not pin on crystalline defects. Long-range order in the ground state is associated with localized electron orbitals in a correlated two-phase field, which provides for flux quantization in units of h/2e on the macroscopic scale larger than the coherence length, without the need for a macroscopic pair wave function. While much of the formalism for this picture may carry over from conventional BCS theory, this picture makes distinct predictions for observable structures on the microscopic and mesoscopic scales.