Diamagnetic Length-Scales of Condon Domain Phase in Lifschitz-Kosevich-Shoenberg Approximation

TL;DR

This paper theoretically investigates the diamagnetic length scales of Condon domains in normal metals using the Lifschitz-Kosevich-Shoenberg approximation, highlighting the influence of electron correlations and experimental conditions.

Contribution

It introduces a theoretical framework for calculating diamagnetic length scales of Condon domains considering electron correlations and experimental parameters.

Findings

Diamagnetic lengths depend on temperature, magnetic field, and sample purity.

The theory aligns well with existing experimental data.

Electron correlations significantly influence domain properties.

Abstract

Equilibrium properties of non-uniform diamagnetic phase in normal metals (Condon domains) are studied theoretically in the framework of Lifschitz-Kosevich-Shoenberg (LKS) approximation. It is found that characteristic diamagnetic lengths of the phase, e. g. a period of domain structure and width of interface boundary between domains, as well as specific surface energy of domain wall, are strongly affected by electron correlations and depend on temperature, magnetic field and purity of the sample. The developed theory is in a good agreement with existent experiment data.