Temperature and Magnetic Field Dependencies of Condon Domain Phase in Lifschitz-Kosevich-Shoenberg Approximation

TL;DR

This paper investigates how temperature and magnetic field influence the formation and stability of Condon domains in a strongly correlated electron gas, highlighting the dependencies within the Lifschitz-Kosevich-Shoenberg approximation.

Contribution

It provides a theoretical analysis of the temperature and magnetic field effects on Condon domains using the Lifschitz-Kosevich-Shoenberg approximation, emphasizing impurity effects.

Findings

Magnetic induction splitting depends strongly on temperature and magnetic field.

The existence range of Condon domains varies with impurities.

The phase behavior is characterized within the Lifschitz-Kosevich-Shoenberg framework.

Abstract

The temperature and magnetic field behavior of non-uniform diamagnetic phase of strongly correlated electron gas at the conditions of dHvA effect is analyzed. It is shown, that in the framework of Lifschitz-Kosevich-Shoenberg approximation the magnetic induction splitting, as well as the range of existence of Condon domains, are characterized by strong dependencies on temperature, magnetic field and impurities of the sample.