2017
DOI: 10.1140/epjc/s10052-017-5232-8
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Thermal spectrum of pseudo-scalar glueballs and Debye screening mass from holography

Abstract: The finite temperature spectrum of pseudo-scalar glueballs in a plasma is studied using a holographic model. The 0 −+ glueball is represented by a pseudo-scalar (axion) field living in a five dimensional geometry that comes from a solution of Einstein equations for gravity coupled with a dilaton scalar field. The spectral function obtained from the model shows a clear peak corresponding to the quasi-particle ground state. Analyzing the variation of the position of the peak with temperature, we describe the the… Show more

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Cited by 8 publications
(8 citation statements)
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“…[82] and applied in holographic QCD [83][84][85][86]. There are also discussions about Debye screening masses extracted from the spatial correlation functions of CT -odd operator TrF µνF µν [87,88], the pseudo-scalar glueballs [89] and the Polyakov loops [90]. The Debye screening mass is shown to increase linearly with T [88], which is consistent with the 4D studies.…”
Section: Introductionsupporting
confidence: 72%
“…[82] and applied in holographic QCD [83][84][85][86]. There are also discussions about Debye screening masses extracted from the spatial correlation functions of CT -odd operator TrF µνF µν [87,88], the pseudo-scalar glueballs [89] and the Polyakov loops [90]. The Debye screening mass is shown to increase linearly with T [88], which is consistent with the 4D studies.…”
Section: Introductionsupporting
confidence: 72%
“…Here we have found the approximate expressions of glueball energies ω (1) and ω (3) by considering the sub-leading order terms upto O(ω 0 ) and O(ω −2 ) respectively, starting from the leading order O(ω) on the left-hand-side of (8). Now the energy or mass ratio of the first exited state to the ground state are ω (1) * /ω (1) = 1.60371 and ω (3) * /ω (3) = The Lattice calculation has found this ratio 1.4602 [21], where m −+ = 2.477GeV and m * −+ = 3.617GeV. So for the second approximation ω (3) , the holographic result gets better accuracy.…”
mentioning
confidence: 96%
“…Also the d + 1 dimensional gravity background should not have the SO(d, 2) symmetry, so that the corresponding (d − 1) + 1 dimensional gauge theory is non-conformal which ensures the existence of a Λ QCD -like fixed point. Considering these two properties of QCD, there are few empirical models to study the glueballs in the holographic QCD [15,[19][20][21]. But those models are not directly connected to the ten dimensional supergravity or superstring theory.…”
mentioning
confidence: 99%
“…Thus, in the following we have studied the graviton spectrum when a BH background is considered in order to describe the mass dependence on the temperature of the environment and compare the new result with the previous calculations. We recall that much research has been carried out to determine the deconfinement temperature and the behaviour of the glueball and meson spectra after the phase transition [19][20][21].…”
Section: Introductionmentioning
confidence: 99%