Heating up the BIon

Gianluca Grignani; Marta Orselli; Niels Anne Jacob Obers; Troels Harmark; Andrea Marini

doi:10.1007/jhep06(2011)058

Heating up the BIon

Gianluca Grignani, Marta Orselli, Niels Anne Jacob Obers, Troels Harmark, Andrea Marini

60 Citations (Scopus)

Abstract

We propose a new method to consider D-brane probes in thermal backgrounds. The method builds on the recently developed blackfold approach to higher-dimensional black holes. While D-brane probes in zero-temperature backgrounds are well-described by the Dirac-Born-Infeld (DBI) action, this method addresses how to probe thermal back- grounds. A particularly important feature is that the probe is in thermal equilibrium with the background. We apply our new method to study the thermal generalization of the BIon solution of the DBI action. The BIon solution is a configuration in at space of a D-brane and a parallel anti-D-brane connected by a wormhole with F-string charge. In our thermal generalization, we put this configuration in hot at space. We find that the finite temperature system behaves qualitatively different than its zero-temperature coun- terpart. In particular, for a given separation between the D-brane and anti-D-brane, while at zero temperature there are two phases, at finite temperature there are either one or three phases available.

Original language	English
Journal	Journal of High Energy Physics (Online)
Volume	2011
Issue number	6, 058
Pages (from-to)	1106
Number of pages	36
ISSN	1126-6708
DOIs	https://doi.org/10.1007/jhep06(2011)058
Publication status	Published - 1 Jun 2011

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title = "Heating up the BIon",

abstract = "We propose a new method to consider D-brane probes in thermal backgrounds. The method builds on the recently developed blackfold approach to higher-dimensional black holes. While D-brane probes in zero-temperature backgrounds are well-described by the Dirac-Born-Infeld (DBI) action, this method addresses how to probe thermal back- grounds. A particularly important feature is that the probe is in thermal equilibrium with the background. We apply our new method to study the thermal generalization of the BIon solution of the DBI action. The BIon solution is a configuration in at space of a D-brane and a parallel anti-D-brane connected by a wormhole with F-string charge. In our thermal generalization, we put this configuration in hot at space. We find that the finite temperature system behaves qualitatively different than its zero-temperature coun- terpart. In particular, for a given separation between the D-brane and anti-D-brane, while at zero temperature there are two phases, at finite temperature there are either one or three phases available.",

author = "Gianluca Grignani and Marta Orselli and Obers, {Niels Anne Jacob} and Troels Harmark and Andrea Marini",

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T1 - Heating up the BIon

AU - Grignani, Gianluca

AU - Orselli, Marta

AU - Obers, Niels Anne Jacob

AU - Harmark, Troels

AU - Marini, Andrea

PY - 2011/6/1

Y1 - 2011/6/1

N2 - We propose a new method to consider D-brane probes in thermal backgrounds. The method builds on the recently developed blackfold approach to higher-dimensional black holes. While D-brane probes in zero-temperature backgrounds are well-described by the Dirac-Born-Infeld (DBI) action, this method addresses how to probe thermal back- grounds. A particularly important feature is that the probe is in thermal equilibrium with the background. We apply our new method to study the thermal generalization of the BIon solution of the DBI action. The BIon solution is a configuration in at space of a D-brane and a parallel anti-D-brane connected by a wormhole with F-string charge. In our thermal generalization, we put this configuration in hot at space. We find that the finite temperature system behaves qualitatively different than its zero-temperature coun- terpart. In particular, for a given separation between the D-brane and anti-D-brane, while at zero temperature there are two phases, at finite temperature there are either one or three phases available.

AB - We propose a new method to consider D-brane probes in thermal backgrounds. The method builds on the recently developed blackfold approach to higher-dimensional black holes. While D-brane probes in zero-temperature backgrounds are well-described by the Dirac-Born-Infeld (DBI) action, this method addresses how to probe thermal back- grounds. A particularly important feature is that the probe is in thermal equilibrium with the background. We apply our new method to study the thermal generalization of the BIon solution of the DBI action. The BIon solution is a configuration in at space of a D-brane and a parallel anti-D-brane connected by a wormhole with F-string charge. In our thermal generalization, we put this configuration in hot at space. We find that the finite temperature system behaves qualitatively different than its zero-temperature coun- terpart. In particular, for a given separation between the D-brane and anti-D-brane, while at zero temperature there are two phases, at finite temperature there are either one or three phases available.

U2 - 10.1007/jhep06(2011)058

DO - 10.1007/jhep06(2011)058

M3 - Journal article

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VL - 2011

SP - 1106

JO - Journal of High Energy Physics (Online)

JF - Journal of High Energy Physics (Online)

IS - 6, 058

ER -

Heating up the BIon

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