Coherent Lattice Vibrations in Superconductors

TL;DR

This paper proposes that superconductivity involves a macroscopic coherent standing-wave pattern of electrons and lattice vibrations, which could be observed experimentally and may be universal across different types of superconductors.

Contribution

It extends Kadin's real-space model to a macroscopic coherent standing-wave pattern, providing a new perspective on the nature of superconducting lattice vibrations.

Findings

Coherent standing-wave patterns can form a waveguide for supercurrent.

Such vibrations are observable below Tc with diffraction techniques.

The model may apply to unconventional superconductors like cuprates.

Abstract

A recent analysis by Kadin has noted that the superconducting wavefunction within the BCS theory may be represented in real-space as a spherical electronic orbital (on the scale of the coherence length) coupled to a standing-wave lattice vibration. This lattice vibration, effectively a bound phonon, has wavevector 2kf and a near-resonant frequency (on the order of the Debye frequency) that maximizes the attractive electrostatic interaction energy with the electronic orbital. The present paper extends this picture to a coherent standing-wave pattern of electron and phonon waves that traverses the entire superconductor on the macroscopic scale. These parallel planes form a diffractive waveguide for electron waves traveling parallel to the planes, permitting lossless supercurrent. A similar picture may be extended to unconventional superconductors such as the cuprates, with an array of standing spin waves rather than phonons. Such coherent lattice vibrations should be universal and distinctive indicators of the superconducting state, and should be observable below Tc using standard x-ray and neutron diffraction techniques. Further implications of this picture are discussed.