Functional dependence of Hall viscosity induced transverse voltage in two-dimensional Fermi liquids

Matthaiakakis, Ioannis; Fernández, David Rodríguez; Tutschku, Christian; Hankiewicz, Ewelina M.; Erdmenger, Johanna; Meyer, René

doi:10.1103/physrevb.101.045423

Cited by 15 publications

(9 citation statements)

References 38 publications

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“…The results for the non-local thermal conductivity and viscosity are given in Eqs. (58), and (63). The transport coefficients show pronounced resonance features at vq ≈ ω where q and ω are the wavenumber and frequency of the applied electric field or thermal gradient (see Figs.…”

Section: Resultsmentioning

confidence: 99%

Non-local hydrodynamic transport and collective excitations in Dirac fluids

Kiselev,

Schmalian

2020

Preprint

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We study the response of a Dirac fluid to electric fields and thermal gradients at finite wavenumbers and frequencies in the hydrodynamic regime. We find that non-local transport in the hydrodynamic regime is governed by infinite set of kinetic modes that describe non-collinear scattering events in different angular harmonic channels. The scattering rates of these modes τ −1 m increase as |m|, where m labels the angular harmonics. In an earlier publication, we pointed out that this dependence leads to anomalous, Lévy-flight-like phase space diffusion [1]. Here, we show how this surprisingly simple, non-analytic dependence allows us to obtain exact expressions for the non-local heat and charge conductivities. The peculiar dependence of the scattering rates on m also leads to a non-trivial structure of collective excitations: Besides the well known plasmon, second sound and diffusive modes, we find non-degenerate damped modes corresponding to excitations of higher angular harmonics. We use these results to investigate the transport of a Dirac fluid through Poiseuille-type geometries of different widths, and to study the response to surface acoustic waves in graphene-piezoelectric devices.

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Section: Resultsmentioning

confidence: 99%

Non-local hydrodynamic transport and collective excitations in Dirac fluids

Kiselev,

Schmalian

2020

Preprint

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“…To shed light on the generic low energy properties of such quantum Hall states, we construct an effective action for systems with a semi-Dirac phase. Our construction contributes to the quest of understanding Hall viscosities; non-dissipative transport coefficients that emerge in the context of topological order [19][20][21][22][23][24][25], fluid dynamics [26][27][28][29][30][31][32][33][34][35][36][37] or active matter [38][39][40][41][42][43]. Initially thought as an elusive transport property, Hall viscosity has been experimentally identified in both hard- [44] and soft- [45] condensed matter experiments.…”

Section: δ<0 δ=0 δ>0mentioning

confidence: 98%

Quantum Hall effective action for anisotropic Dirac semi-metal

Hoyos,

Lier,

Peña-Benitez

et al. 2020

Preprint

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We present a study of Hall transport in semi-Dirac critical phases. The construction is based on a covariant formulation of relativistic systems with spatial anisotropy. Geometric data together with external electromagnetic fields is used to devise an expansion procedure that leads to a lowenergy effective action consistent with the discrete P T symmetry that we impose. We use the action to discuss terms contributing the Hall transport and extract the coefficients. We also discuss the associated scaling symmetry.

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“…In the presence of an external magnetic field we need to add the Lorentz force as well as a Hall viscosity ν H into the equation of motion. For a steady flow we thus have [80][81][82][83][84]…”

Section: Magnetoresistance and Hall Resistancementioning

confidence: 99%

Transport properties of strongly coupled electron-phonon liquids

Levchenko,

Schmalian

2020

Preprint

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In this work we consider the hydrodynamic behavior of a coupled electron-phonon fluid, focusing on electronic transport under the conditions of strong phonon drag. This regime occurs when the rate of phonon equilibration due to e.g. umklapp scattering is much slower than the rate of normal electron-phonon collisions. Then phonons and electrons form a coupled out-of-equilibrium state where the total quasi-momentum of the electron-phonon fluid is conserved. A joint flow-velocity emerges as a collective hydrodynamic variable. We derive the equation of motion for this fluid from the underlying microscopic kinetic theory and elucidate its effective viscosity and thermal conductivity. In particular, we derive decay times of arbitrary harmonics of the distribution function and reveal its corresponding super-diffusive relaxation on the Fermi surface. We further consider several applications of this theory to magneto-transport properties in the Hallbar and Corbino-disk geometries, relevant to experiments. In our analysis we allow for general boundary conditions that cover the crossover from no-slip to no-stress flows. Our approach also covers a crossover from the Stokes to the Ohmic regime under the conditions of the Gurzhi effect. In addition, we consider the frequency dependence of the surface impedance and non-equilibrium noise. For the latter, we notice that in the diffusive regime, a Fokker-Planck approximation, applied to the electron-phonon collision integral in the Eliashberg form, reduces it to a differential operator with Burgers type nonlinearity. As a result, the non-equilibrium distribution function has a shock-wave structure in the energy domain. The consequence of this behavior for the Fano factor of the noise is investigated. In conclusion we discuss connections and limitations of our results in the context of recent electron-phonon drag measurements in Dirac and Weyl semimetals, and layout directions for further extensions and developments.

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Functional dependence of Hall viscosity induced transverse voltage in two-dimensional Fermi liquids

Cited by 15 publications

References 38 publications

Non-local hydrodynamic transport and collective excitations in Dirac fluids

Non-local hydrodynamic transport and collective excitations in Dirac fluids

Quantum Hall effective action for anisotropic Dirac semi-metal

Transport properties of strongly coupled electron-phonon liquids

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