Exact solution of Dirac-Rosen-Morse problem in curved space-time

IF 1.1 4区物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY

Canadian Journal of Physics Pub Date : 2023-06-30 DOI:10.1139/cjp-2023-0146

M. D. de Oliveira

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引用次数: 1

Abstract

In this work we extend the analysis of the relativistic Dirac-Rosen-Morse problem in curved space-time. For that, we consider the Dirac equation in curved space-time with line element ds² = (1+α² U(r))²(dt²- dr²) - r²dθ²-r²sin²θ dΦ², where α² is fine structural constant, U(r) is an scalar potential and in the presence of the electromagnetic field A_μ = (V(r),cA(r),0,0). Because of the spherical symmetry, the angular spinor is given in terms of the spherical harmonics. For the radial spinor, we applying a unitary transformation and defining the vector component of the electromagnetic field A(r) written as a function of V(r) and U(r), so solve the radial spinor for Dirac-Rosen-Morse problem. Graphical analyzes were performed comparing the eigenenergies and the probability densities in curved and flat space-time in order to visualize the influence of curvature in space-time on the two-component radial spinor, with the upper and lower components representing the particle and antiparticle, respectively.

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弯曲时空中Dirac-Rosen-Morse问题的精确解

在这项工作中，我们扩展了弯曲时空中相对论性狄拉克-罗森-莫尔斯问题的分析。为此，我们考虑线元ds2 = (1+α2 U(r))2(dt2- dr2) - r2dθ -r2sin2θ dΦ2的弯曲时空中的Dirac方程，其中α2为精细结构常数，U(r)为标量势，在电磁场存在下，μ = (V(r)，cA(r)，0,0)。由于球对称，角旋量用球谐波的形式给出。对于径向旋量，我们应用幺正变换，将电磁场的矢量分量a (r)定义为V(r)和U(r)的函数，从而求解了径向旋量的Dirac-Rosen-Morse问题。为了可视化时空曲率对双分量径向旋量的影响，对弯曲时空和平面时空中的特征能量和概率密度进行了图形化分析，上分量和下分量分别代表粒子和反粒子。

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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来源期刊

Canadian Journal of Physics 物理-物理：综合

CiteScore

2.30

自引率

8.30%

发文量

审稿时长

1.7 months

期刊介绍： The Canadian Journal of Physics publishes research articles, rapid communications, and review articles that report significant advances in research in physics, including atomic and molecular physics; condensed matter; elementary particles and fields; nuclear physics; gases, fluid dynamics, and plasmas; electromagnetism and optics; mathematical physics; interdisciplinary, classical, and applied physics; relativity and cosmology; physics education research; statistical mechanics and thermodynamics; quantum physics and quantum computing; gravitation and string theory; biophysics; aeronomy and space physics; and astrophysics.