Modified Fermi Energy of Electrons in a Superhigh Magnetic Field

TL;DR

This paper derives a new formula for the electron Fermi energy in superhigh magnetic fields of magnetars, accounting for Landau-level stability, which impacts electron density and pressure, aiding neutron star studies.

Contribution

It introduces a novel Landau-level stability coefficient and a general formula for electron Fermi energy in superhigh magnetic fields, improving upon previous models.

Findings

Enhanced electron number density in superhigh magnetic fields.

Increased electron Fermi energy and degeneracy pressure.

Redistribution of electrons across Landau levels with increasing magnetic field.

Abstract

In this paper, we investigate the electron Landau-level stability and its influence on the electron Fermi energy, $E_{\rm F}(e)$, in the circumstance of magnetars, which are powered by magnetic field energy. In a magnetar, the Landau levels of degenerate and relativistic electrons are strongly quantized. A new quantity $g_{n}$, the electron Landau-level stability coefficient is introduced. According to the requirement that $g_{n}$ decreases with increasing the magnetic field intensity $B$, the magnetic-field index $\beta$ in the expression of $E_{\rm F}(e)$ must be positive. By introducing the Dirac$-\delta$ function, we deduce a general formulae for the Fermi energy of degenerate and relativistic electrons, and obtain a particular solution to $E_{\rm F}(e)$ in a superhigh magnetic field (SMF). This solution has a low magnetic-field index of $\beta=1/6$, compared with the previous one, and works when $\rho\geq 10^{7}$~g cm$^{-3}$ and $B_{\rm cr}\ll B\leq 10^{17}$~Gauss. By modifying the phase space of relativistic electrons, a SMF can enhance the electron number density $n_e$, and decrease the maximum of electron Landau level number, which results in a redistribution of electrons. According to Pauli exclusion principle, the degenerate electrons will fill quantum states from the lowest Landau level to the highest Landau level. As $B$ increases, more and more electrons will occupy higher Landau levels, though $g_{n}$ decreases with the Landau level number $n$. The enhanced $n_{e}$ in a SMF means an increase in the electron Fermi energy and an increase in the electron degeneracy pressure. The results are expected to facilitate the study of the weak-interaction processes inside neutron stars and the magnetic-thermal evolution mechanism for megnetars.