141 research outputs found
Quantization of rotating linear dilaton black holes
In this paper, we focus on the quantization of dimensional rotating
linear dilaton black hole (RLDBH) spacetime describing an action, which emerges
in the Einstein-Maxwell-Dilaton-Axion (EMDA) theory. RLDBH spacetime has a
non-asymptotically flat (NAF) geometry. When the rotation parameter " "
vanishes, the spacetime reduces to its static form, the so-called linear
dilaton black hole (LDBH) metric. Under scalar perturbations, we show that the
radial equation reduces to a hypergeometric differential equation. Using the
boundary conditions of the quasinormal modes (QNMs), we compute the associated
complex frequencies of the QNMs. In a particular case, QNMs are applied in the
rotational adiabatic invariant quantity, and we obtain the quantum entropy/area
spectra of the RLDBH. Both spectra are found to be discrete and equidistant,
and independent of parameter despite the modulation of QNMs by this
parameter
Resonance Spectra of Caged Stringy Black Hole and Its Spectroscopy
The Maggiore's method (MM), which evaluates the transition frequency that
appears in the adiabatic invariant from the highly damped quasinormal mode
(QNM) frequencies, is used to investigate the entropy/area spectra of the
Garfinkle--Horowitz--Strominger black hole (GHSBH). Instead of the ordinary
QNMs, we compute the boxed QNMs (BQNMs) that are the characteristic resonance
spectra of the confined scalar fields in the GHSBH geometry. For this purpose,
we assume that the GHSBH has a confining cavity (mirror) placed in the vicinity
of the event horizon. We then show how the complex resonant frequencies of the
caged GHSBH are computed using the Bessel differential equation that arises
when the scalar perturbations around the event horizon are considered. Although
the entropy/area is characterized by the GHSBH parameters, their quantization
is shown to be independent of those parameters. However, both spectra are
equally spaced.Comment: New References have been added. Thanks to Prof. Carlos A. R. Herdeir
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