Charged dilatonic black holes and their transport properties

B. Goutéraux; B. S. Kim; R. Meyer

doi:10.1002/prop.201100029

Charged dilatonic black holes and their transport properties

B. Goutéraux
, B. S. Kim
, R. Meyer

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

Abstract

We briefly explain the consistency conditions imposed on the effective holographic theories, which are parameterized by two real exponents (γ,δ) that control the IR dynamics. The general scaling of DC resistivity with temperature at low temperature and AC conductivity at low frequency across the whole (γ,δ) plane are explained. There is a codimension-one region where the DC resistivity is linear in the temperature. For massive carriers, it is shown that when the scalar operator is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for (2+1)-dimensional systems. Regions are identified where the theory at finite density is a Mott-like insulator. This contribution is based on (C. Charmousis, et al. J. High Energy Phys. 1011, 151 (2010)) [1] with emphasis on the transport properties of charged dilatonic black holes with potential.

Original language	English
Pages (from-to)	723-729
Number of pages	7
Journal	Fortschritte der Physik
Volume	59
Issue number	7-8
DOIs	https://doi.org/10.1002/prop.201100029
Publication status	Published - 1 Jul 2011
Externally published	Yes

Keywords

Dilatonic black holes
Effective holographic theories.
Transport properties

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10.1002/prop.201100029

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title = "Charged dilatonic black holes and their transport properties",

abstract = "We briefly explain the consistency conditions imposed on the effective holographic theories, which are parameterized by two real exponents (γ,δ) that control the IR dynamics. The general scaling of DC resistivity with temperature at low temperature and AC conductivity at low frequency across the whole (γ,δ) plane are explained. There is a codimension-one region where the DC resistivity is linear in the temperature. For massive carriers, it is shown that when the scalar operator is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for (2+1)-dimensional systems. Regions are identified where the theory at finite density is a Mott-like insulator. This contribution is based on (C. Charmousis, et al. J. High Energy Phys. 1011, 151 (2010)) [1] with emphasis on the transport properties of charged dilatonic black holes with potential.",

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T1 - Charged dilatonic black holes and their transport properties

AU - Goutéraux, B.

AU - Kim, B. S.

AU - Meyer, R.

PY - 2011/7/1

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N2 - We briefly explain the consistency conditions imposed on the effective holographic theories, which are parameterized by two real exponents (γ,δ) that control the IR dynamics. The general scaling of DC resistivity with temperature at low temperature and AC conductivity at low frequency across the whole (γ,δ) plane are explained. There is a codimension-one region where the DC resistivity is linear in the temperature. For massive carriers, it is shown that when the scalar operator is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for (2+1)-dimensional systems. Regions are identified where the theory at finite density is a Mott-like insulator. This contribution is based on (C. Charmousis, et al. J. High Energy Phys. 1011, 151 (2010)) [1] with emphasis on the transport properties of charged dilatonic black holes with potential.

AB - We briefly explain the consistency conditions imposed on the effective holographic theories, which are parameterized by two real exponents (γ,δ) that control the IR dynamics. The general scaling of DC resistivity with temperature at low temperature and AC conductivity at low frequency across the whole (γ,δ) plane are explained. There is a codimension-one region where the DC resistivity is linear in the temperature. For massive carriers, it is shown that when the scalar operator is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for (2+1)-dimensional systems. Regions are identified where the theory at finite density is a Mott-like insulator. This contribution is based on (C. Charmousis, et al. J. High Energy Phys. 1011, 151 (2010)) [1] with emphasis on the transport properties of charged dilatonic black holes with potential.

KW - Dilatonic black holes

KW - Effective holographic theories.

KW - Transport properties

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JF - Fortschritte der Physik

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ER -

Charged dilatonic black holes and their transport properties

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