Higher-n triangular dilatonic black holes

Anton Zadora; Dmitri V. Gal'tsov; Chiang Mei Chen

doi:10.1016/j.physletb.2018.02.017

Higher-n triangular dilatonic black holes

Anton Zadora, Dmitri V. Gal'tsov, Chiang Mei Chen

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Dilaton gravity with the form fields is known to possess dyon solutions with two horizons for the discrete “triangular” values of the dilaton coupling constant a=n(n+1)/2. This sequence first obtained numerically and then explained analytically as consequence of the regularity of the dilaton, should have some higher-dimensional and/or group theoretical origin. Meanwhile, this origin was explained earlier only for n=1,2 in which cases the solutions were known analytically. We extend this explanation to n=3,5 presenting analytical triangular solutions for the theory with different dilaton couplings a,b in electric and magnetic sectors in which case the quantization condition reads ab=n(n+1)/2. The solutions are derived via the Toda chains for B₂ and G₂ Lie algebras. They are found in the closed form in general D space–time dimensions. Solutions satisfy the entropy product rules indicating on the microscopic origin of their entropy and have negative binding energy in the extremal case.

Original language	English
Pages (from-to)	249-256
Number of pages	8
Journal	Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics
Volume	779
DOIs	https://doi.org/10.1016/j.physletb.2018.02.017
State	Published - 10 Apr 2018

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10.1016/j.physletb.2018.02.017

Black Hole Physics: Holographic Duality and Applications
Chen, C.-M. (PI)
1/08/17 → 31/07/18
Project: Research

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title = "Higher-n triangular dilatonic black holes",

abstract = "Dilaton gravity with the form fields is known to possess dyon solutions with two horizons for the discrete “triangular” values of the dilaton coupling constant a=n(n+1)/2. This sequence first obtained numerically and then explained analytically as consequence of the regularity of the dilaton, should have some higher-dimensional and/or group theoretical origin. Meanwhile, this origin was explained earlier only for n=1,2 in which cases the solutions were known analytically. We extend this explanation to n=3,5 presenting analytical triangular solutions for the theory with different dilaton couplings a,b in electric and magnetic sectors in which case the quantization condition reads ab=n(n+1)/2. The solutions are derived via the Toda chains for B2 and G2 Lie algebras. They are found in the closed form in general D space–time dimensions. Solutions satisfy the entropy product rules indicating on the microscopic origin of their entropy and have negative binding energy in the extremal case.",

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T1 - Higher-n triangular dilatonic black holes

AU - Zadora, Anton

AU - Gal'tsov, Dmitri V.

AU - Chen, Chiang Mei

PY - 2018/4/10

Y1 - 2018/4/10

N2 - Dilaton gravity with the form fields is known to possess dyon solutions with two horizons for the discrete “triangular” values of the dilaton coupling constant a=n(n+1)/2. This sequence first obtained numerically and then explained analytically as consequence of the regularity of the dilaton, should have some higher-dimensional and/or group theoretical origin. Meanwhile, this origin was explained earlier only for n=1,2 in which cases the solutions were known analytically. We extend this explanation to n=3,5 presenting analytical triangular solutions for the theory with different dilaton couplings a,b in electric and magnetic sectors in which case the quantization condition reads ab=n(n+1)/2. The solutions are derived via the Toda chains for B2 and G2 Lie algebras. They are found in the closed form in general D space–time dimensions. Solutions satisfy the entropy product rules indicating on the microscopic origin of their entropy and have negative binding energy in the extremal case.

AB - Dilaton gravity with the form fields is known to possess dyon solutions with two horizons for the discrete “triangular” values of the dilaton coupling constant a=n(n+1)/2. This sequence first obtained numerically and then explained analytically as consequence of the regularity of the dilaton, should have some higher-dimensional and/or group theoretical origin. Meanwhile, this origin was explained earlier only for n=1,2 in which cases the solutions were known analytically. We extend this explanation to n=3,5 presenting analytical triangular solutions for the theory with different dilaton couplings a,b in electric and magnetic sectors in which case the quantization condition reads ab=n(n+1)/2. The solutions are derived via the Toda chains for B2 and G2 Lie algebras. They are found in the closed form in general D space–time dimensions. Solutions satisfy the entropy product rules indicating on the microscopic origin of their entropy and have negative binding energy in the extremal case.

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JO - Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics

JF - Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics

ER -

Higher-n triangular dilatonic black holes

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Black Hole Physics: Holographic Duality and Applications

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