Superconductors: The Standing Wave Model and Super-fluid Density

TL;DR

This paper introduces a standing wave model for superconductivity, deriving key relations from first principles and connecting superfluid density to critical temperature, with comparisons to experimental data.

Contribution

It presents a novel microscopic model of superconductivity based on standing waves, deriving fundamental relations and linking superfluid density to critical temperature.

Findings

Derived a microscopic London relation from first principles.

Established a relation between superfluid density and critical temperature.

Compared theoretical results with experimental data from Bozovic et al.

Abstract

The standing wave model describes the well-known phenomenon of superconductivity in a new way [1]. Starting from a new definition of superconductivity, a microscopic London relation is derived from first principles. The relation between the macroscopic electric current and the field is derived from this microscopic relation. The coherence length as function of the superfluid density is derived from the microscopic theory. The critical temperature as function of the superfluid density is thus obtained. These results are compared to the experimental work of Bozovic et. al. [2].