2011
DOI: 10.1103/physrevd.84.127502
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Application of the confluent Heun functions for finding the quasinormal modes of nonrotating black holes

Abstract: Although finding numerically the quasinormal modes of a nonrotating black hole is a well-studied question, the physics of the problem is often hidden behind complicated numerical procedures aimed at avoiding the direct solution of the spectral system in this case. In this article, we use the exact analytical solutions of the Regge-Wheeler equation and the Teukolsky radial equation, written in terms of confluent Heun functions. In both cases, we obtain the quasinormal modes numerically from spectral condition w… Show more

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Cited by 54 publications
(71 citation statements)
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“…For example, the confluent Heun functions have been worked out in the context of the quasinormal modes for nonrotating black holes [Fiziev and Staicova, 2011] or as solutions to Schrödinger equation, for different rational potential functions, in thick braneworlds [Cunha and Christiansen, 2011].…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…For example, the confluent Heun functions have been worked out in the context of the quasinormal modes for nonrotating black holes [Fiziev and Staicova, 2011] or as solutions to Schrödinger equation, for different rational potential functions, in thick braneworlds [Cunha and Christiansen, 2011].…”
Section: Discussionmentioning
confidence: 99%
“…Thus, because besides leptons, in dense nuclear matter, the nucleons interact among each other through three meson fields: the isoscalar-scalar meson σ, isoscalar vector meson ω and isovector-vector meson ρ, one may assume that currents and charge density produced by the single-particle spinors, as the ones in (22), are actually acting as sources for the Klein-Gordon Gordon equations for the time-and space-like meson fields ∆ − m 2 φ φ = g φ j p ∆ − m 2 φ φ 0 = g φ Q p (38) whereφ = { ω , ρ} and φ 0 = {ω 0 , ρ 0 }, g φ are the respective coupling constants, m φ are the meson masses and (see (21))…”
Section: Discussionmentioning
confidence: 99%
“…o Fiziev is an expert in this topic. Two further articles by him and his collaborator is: Solving systems of transcendental equations involving the Heun functions, [72] and Application of the confluent Heun functions for finding the quasinormal modes of non rotating black holes [73].…”
Section: Some Examples Of the Heun Equation In Physical Applicationsmentioning
confidence: 99%
“…This means that the use of the Heun functions is limited to the routines hidden in the kernel of Maple, which the user cannot change or improve-a situation that makes understanding the numerical problems or avoiding them adequately very difficult. On the positive side, those routines were found by the team to work well enough in many cases (see, for example, the match between theory and numerical results in [8], as well as the other applications of those functions in [9,10]). Yet, there are some peculiarities-there are values of the parameters where the routines break down leading to infinities or to numerical errors.…”
Section: Introductionmentioning
confidence: 99%
“…They occur in the problem of quasi-normal modes (QNM) of rotating and nonrotating black holes, which is to some extent the gravity analogue of the problem of the hydrogen atom. Finding the QNMs is critical to understanding observational data from gravitational wave detectors and proving or refuting the black holes existence ( [11,12] and also [8][9][10]). In this case, one has to solve a two-dimensional connected spectral problem with two complex equations in each of which one encounters the confluent Heun functions.…”
Section: Introductionmentioning
confidence: 99%