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Main Author: Oliveira, R. R. S.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.11560
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author Oliveira, R. R. S.
author_facet Oliveira, R. R. S.
contents In this paper, we determine the relativistic bound-state solutions for the Dirac oscillator (DO) in the curved spacetime of a cloud of strings in $(3+1)$-dimensions, where such solutions are given by the four-component normalized Dirac spinor and by the relativistic energy spectrum. However, unlike in literature, here, we work with the spacetime in two different forms/configurations, that is, both in its original form and in its modified form. To achieve our objective, we work with the curved DO in spherical coordinates, where we use the tetrad formalism. So, by defining a stationary ansatz for the spinor, we obtain two coupled first-order differential equations, and by substituting one equation into the other, we obtain a second-order differential equation. To analytically and exactly solve this differential equation, we use a change of function and of variable. From this, we obtain the well-known Whittaker equation, whose solution is the Whittaker function. Consequently, we obtain the energy spectrum, which is quantized in terms of the radial quantum number $n$ and the angular quantum number $κ$, and explicitly depends on the angular frequency $ω$ (describes the DO), curvature parameter $a$ (describes the cloud of strings), and on the effective rest mass $m_{\text{eff}}$ (describes the rest mass modified by the curvature of spacetime). Besides, we graphically analyze the behavior of the spectrum as a function of $ω$ and $a$ for three different values of $n$ and $κ$, as well as the behavior of the radial probability density for four different values of $κ$, $ω$, and $a$ (with $n=0$).
format Preprint
id arxiv_https___arxiv_org_abs_2605_11560
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The Dirac oscillator in the curved spacetime of a cloud of strings
Oliveira, R. R. S.
High Energy Physics - Theory
In this paper, we determine the relativistic bound-state solutions for the Dirac oscillator (DO) in the curved spacetime of a cloud of strings in $(3+1)$-dimensions, where such solutions are given by the four-component normalized Dirac spinor and by the relativistic energy spectrum. However, unlike in literature, here, we work with the spacetime in two different forms/configurations, that is, both in its original form and in its modified form. To achieve our objective, we work with the curved DO in spherical coordinates, where we use the tetrad formalism. So, by defining a stationary ansatz for the spinor, we obtain two coupled first-order differential equations, and by substituting one equation into the other, we obtain a second-order differential equation. To analytically and exactly solve this differential equation, we use a change of function and of variable. From this, we obtain the well-known Whittaker equation, whose solution is the Whittaker function. Consequently, we obtain the energy spectrum, which is quantized in terms of the radial quantum number $n$ and the angular quantum number $κ$, and explicitly depends on the angular frequency $ω$ (describes the DO), curvature parameter $a$ (describes the cloud of strings), and on the effective rest mass $m_{\text{eff}}$ (describes the rest mass modified by the curvature of spacetime). Besides, we graphically analyze the behavior of the spectrum as a function of $ω$ and $a$ for three different values of $n$ and $κ$, as well as the behavior of the radial probability density for four different values of $κ$, $ω$, and $a$ (with $n=0$).
title The Dirac oscillator in the curved spacetime of a cloud of strings
topic High Energy Physics - Theory
url https://arxiv.org/abs/2605.11560