Crossover of Charge Fluctuations across the Strange Metal Phase Diagram

Husain, Ali; Mitrano, Matteo; Rak, Melinda; Rubeck, Samantha; Uchoa, Bruno; March, Katia; Dwyer, Christian; Schneeloch, John; Zhong, Ruidan; Gu, Genda; Abbamonte, Peter

doi:10.1103/physrevx.9.041062

Cited by 59 publications

(79 citation statements)

References 76 publications

(235 reference statements)

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“…An interesting future direction would be to understand the role of our results in relation to the recent experiments performed in strange metals and quantum critical materials [14,15]. Finally, similar dispersion relations have been discussed in the hydrodynamic description of collective modes in Weyl semimetals [84].…”

Section: Discussionsupporting

confidence: 63%

“…The results are quite different from the weakly coupled paradigm, in the sense that the plasmon modes display an anomalously strong damping. Not only that, but there are recent observations [14,15] which indicate that when increasing the momentum, plasmons stop existing as welldefined quasi-particles and get smoothed out in the collective and incoherent "quantum soup" losing a characteristic momentum scale. The strong damping of plasmons, even at zero momentum, is expected for strongly coupled quantum critical systems and was first observed in a holographic model in [16].…”

Section: )mentioning

confidence: 99%

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Holographic plasmon relaxation with and without broken translations

Baggioli

Gran

Alba

et al. 2019

J. High Energ. Phys.

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We study the dynamics and the relaxation of bulk plasmons in strongly coupled and quantum critical systems using the holographic framework. We analyze the dispersion relation of the plasmonic modes in detail for an illustrative class of holographic bottom-up models. Comparing to a simple hydrodynamic formula, we entangle the complicated interplay between the three least damped modes and shed light on the underlying physical processes. Such as the dependence of the plasma frequency and the effective relaxation time in terms of the electromagnetic coupling, the charge and the temperature of the system. Introducing momentum dissipation, we then identify its additional contribution to the damping. Finally, we consider the spontaneous symmetry breaking (SSB) of translational invariance. As the strength of SSB is increased, we observe a transition between dressed zero sound, the plasmon, and the normal sound controlled by the elastic moduli and the propagation of longitudinal phonons. This crossover is characterized by the disappearance of the plasma frequency gap in the sound mode.

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Section: Discussionsupporting

confidence: 63%

Section: )mentioning

confidence: 99%

Holographic plasmon relaxation with and without broken translations

Baggioli

Gran

Alba

et al. 2019

J. High Energ. Phys.

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“…This is also seen in Eq. (3.7): increasing the plasma frequency by increasing e 2 makes the two purely imaginary modes approach each other and, at a certain critical value of ω p , they collide and form a pair of sound-like modes 3. A similar behaviour was found in[13], however we would not draw a direct analogy since we do not consider spontaneous breaking of translations here.…”

mentioning

confidence: 87%

“…This competition between Γ k and e 2 , which was anticipated in [12] in a metallic setup with irrelevant translation symmetry-breaking, will be important for us in the present situation. 3 In fact, it complicates our search for a featureless density-density response, because we should avoid the regime where the modes become sound-like. In order to prevent this from happening at finite dressing e 2 and momentum k, we focus on the strong momentum-dissipation regime which goes beyond the applicability of the hydrodynamical approximation.…”

Section: Dressing the Hydro Modes With The Coulomb Interactionmentioning

confidence: 99%

“…It is well-established by now that strongly correlated electron systems, in particular high temperature superconductors and strange metals, display anomalous phenomenology [1]; the charge density response is not an exception. For instance, recent momentum resolved electron energy-loss spectroscopy (M-EELS) experiments found that the spectrum of cuprate strange metals cannot be understood in terms of the conventional physics of a coherent plasmon [2,3]. These unconventional condensed matter systems require unconventional theoretical approaches to describe their phenomenology and the holographic duality provides a suitable framework for this task [4].…”

Section: Introductionmentioning

confidence: 99%

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Charge density response and fake plasmons in holographic models with strong translation symmetry breaking

Andrade¹,

Krikun²,

Romero-Bermúdez³

2019

J. High Energ. Phys.

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We study the charge density response in holographic models with explicit translation symmetry breaking which is relevant in the IR; in particular, we focus on Q-lattices and the Bianchi 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 plasmonin 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 Fermiliquid paradigm.

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Coulomb effects in electronic transport

Narozhny

2023

Contrib. Plasma Phys

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Charge transport in metals and semiconductors is often dominated by electron‐impurity and electron–phonon scattering. Coulomb effects could be found in small corrections to the leading behavior, drag effects in specially fabricated samples, compensated semimetals, and hydrodynamic phenomena in ultra‐pure materials. In contrast, electrical resistivity in strongly correlated systems is poorly understood. Understanding the fate of electron–phonon scattering in these materials may offer a route towards future advancements.

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Crossover of Charge Fluctuations across the Strange Metal Phase Diagram

Cited by 59 publications

References 76 publications

Holographic plasmon relaxation with and without broken translations

Holographic plasmon relaxation with and without broken translations

Charge density response and fake plasmons in holographic models with strong translation symmetry breaking

Coulomb effects in electronic transport

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