Abstract
We study the charge density response in holographic models with explicit trans- lation symmetry breaking which is relevant in IR. In particular, we focus on Q-lattices and the Bianchy VII helix. We show that the hydrodynamic sound mode is removed from the spectrum due to the strong momentum relaxation and therefore, the usual treatment of the plasmon as Coulomb-dressed zero sound does not apply. Furthermore, the dominant coherent modes in the longitudinal channel, which control the neutral density-density correlator, are the diffusive modes. We show these modes are strongly suppressed when the boundary Coulomb interaction is turned on. This renders the low frequency charge density response spectrum completely incoherent and featureless.At intermediate frequencies, we observe a broad feature — the fake plasmon — in the dressed correlator, which could be confused with an overdamped plasmon. However, its gap is set by the scale of translation symmetry breaking instead of the plasma frequency. This broad feature originates from the non-hydrodynamic sector of the holographic spectrum, and therefore, its behaviour, typical of strongly correlated quantum critical systems with holographic duals, deviates from the standard Fermi-liquid paradigm.
Highlights
At intermediate frequencies, we observe a broad feature — the fake plasmon — in the dressed correlator, which could be confused with an overdamped plasmon
We study the charge density response in holographic models with explicit translation symmetry breaking which is relevant in IR
In this work we have studied the quasinormal mode spectrum and the charge density response function in holographic models with strong IR-relevant explicit translation symmetry breaking
Summary
In order to remove the sound mode from the spectrum of the neutral holographic model, we introduce explicit translational symmetry breaking. The spectrum of hydrodynamics with weakly broken translations includes the modes corresponding to the transverse momentum These are the momentum fluctuations in the directions perpendicular to the wave-vector. When translations are broken explicitly, the spectrum of hydrodynamic modes at long wavelengths consists of only the purely imaginary modes corresponding to either the diffusion of the conserved quantities (energy, U(1)-charges, etc), or the dissipation of the non-conserved quantities (i.e. longitudinal momentum). This feature has been recently studied in [18]. We discuss how this spectrum is affected once we take into account the long range Coulomb interaction of the charge density
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