Electron stars for holographic metallic criticality

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Abstract

We refer to the ground state of a gravitating, charged ideal fluid of fermions held at a finite chemical potential as an `electron star'. In a holographic setting, electron stars are candidate gravity duals for strongly interacting finite fermion density systems. We show how electron stars develop an emergent Lifshitz scaling at low energies. This IR scaling region is a consequence of the two way interaction between emergent quantum critical bosonic modes and the finite density of fermions. By integrating from the IR region to an asymptotically AdS_4 spacetime, we compute basic properties of the electron stars, including their electrical conductivity. We emphasize the challenge of connecting UV and IR physics in strongly interacting finite density systems.

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Most cited references 25

Record: found
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Article: not found

Quantum critical phenomena

John Hertz (1976)

0 comments Cited 857 times – based on 0 reviews      Review now

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Record: found
Abstract: not found
Article: not found

Ground-State Energy of a Many-Fermion System. II

J. M. Luttinger, J. Ward (1960)

0 comments Cited 645 times – based on 0 reviews      Review now

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Record: found
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Is Open Access

Building an AdS/CFT superconductor

Gary T. Horowitz, Christopher Herzog, Sean Hartnoll (2008)

We show that a simple gravitational theory can provide a holographically dual description of a superconductor. There is a critical temperature, below which a charged condensate forms via a second order phase transition and the (DC) conductivity becomes infinite. The frequency dependent conductivity develops a gap determined by the condensate. We find evidence that the condensate consists of pairs of quasiparticles.