The Physics of Magnetars II - The Electron Fermi Energy of and the Origin of High X-ray Luminosity of Magnetars

Q. Peng, Jie Zhang, C. Chou, Z. Gao
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引用次数: 2

Abstract

In this paper we discuss in detail the quantization of Landau energy levels of a strongly magnetized and completely degenerate relativistic electron gas in neutron stars. In particular, we focus on the Fermi energy dependence of the magnetic field for a relativistic electron gas in the superstrong magnetic field of magnetars. We would like to point out that some of the results concerning the microscopic number density of states of a strongly magnetized electron gas given by well known statistical physics text books are incorrect. The repeated use of these results in the last five decades probably seriously affects the physics of neutron stars and magnetars. The quantization of Landau energy levels is accurately delineated in terms of the Dirac -δ function. Relatively simple calculation shows that the Fermi energy of a relativistic electron gas in magnetars with superstrong magnetic fields (B>B cr , here B cr is the Landau critical magnetic field, B cr = 4.414 × 10 13 gauss ) increases with magnetic field strength as B 1/4 . On the basis of this simple but important new result we are leading naturally to propose a new mechanism for the production of high X-ray luminosity from magnetars.
磁星的物理学II -磁星的电子费米能和高x射线光度的起源
本文详细讨论了中子星中强磁化和完全简并的相对论性电子气体朗道能级的量子化。特别地,我们关注了磁星超强磁场中相对论性电子气体磁场的费米能量依赖。我们要指出,一些众所周知的统计物理教科书给出的关于强磁化电子气体的微观态数密度的结果是不正确的。在过去的50年里,这些结果的反复使用可能严重影响了中子星和磁星的物理学。朗道能级的量子化是用狄拉克-δ函数精确地描述的。相对简单的计算表明,在具有超强磁场的磁星中,相对论性电子气体的费米能量(B>B cr,其中B cr为朗道临界磁场,B cr = 4.414 × 10 13高斯)随磁场强度的增大而增大,为B 1/4。在这个简单但重要的新结果的基础上,我们很自然地提出了磁星产生高x射线光度的新机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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