Collision-dominated nonlinear hydrodynamics in graphene

Briskot, U.; Schütt, Michael; Gornyi, I. V.; Titov, M.; Narozhny, B. N.; Mirlin, A. D.

doi:10.1103/physrevb.92.115426

Cited by 123 publications

(239 citation statements)

References 58 publications

(222 reference statements)

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“…A generalization of our approach to nonlinear hydrodynamics in graphene will be reported in a subsequent publication [38].…”

Section: Discussionmentioning

confidence: 99%

“…In this paper, we are focusing on kinetic coefficients describing dissipative processes in the system within linear response. The nonlinear hydrodynamics of graphene will be discussed in a separate publication [38].…”

Section: Macroscopic Description Of Transport In Monolayer Graphenementioning

confidence: 99%

“…V A 2) the energy and imbalance currents in the two layers have the same direction leading to positive drag. Taking into account finiteness of the corresponding relaxation rates (Appendix D) refines the theory in analogy with including viscous terms into standard hydrodynamic theory [1,38]. The resulting theory contains four differential equations for the energy and imbalance currents [cf.…”

Section: B Mesoscopic System At Charge Neutralitymentioning

confidence: 99%

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Hydrodynamics in graphene: Linear-response transport

et al. 2015

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We develop a hydrodynamic description of transport properties in graphene-based systems, which we derive from the quantum kinetic equation. In the interaction-dominated regime, the collinear scattering singularity in the collision integral leads to fast unidirectional thermalization and allows us to describe the system in terms of three macroscopic currents carrying electric charge, energy, and quasiparticle imbalance. Within this "three-mode" approximation, we evaluate transport coefficients in monolayer graphene as well as in double-layer graphene-based structures. The resulting classical magnetoresistance is strongly sensitive to the interplay between the sample geometry and leading relaxation processes. In small, mesoscopic samples, the macroscopic currents are inhomogeneous, which leads to a linear magnetoresistance in classically strong fields. Applying our theory to double-layer graphene-based systems, we provide a microscopic foundation for a phenomenological description of giant magnetodrag at charge neutrality and find the magnetodrag and Hall drag in doped graphene.

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“…A generalization of our approach to nonlinear hydrodynamics in graphene will be reported in a subsequent publication [38].…”

Section: Discussionmentioning

confidence: 99%

Section: Macroscopic Description Of Transport In Monolayer Graphenementioning

confidence: 99%

Section: B Mesoscopic System At Charge Neutralitymentioning

confidence: 99%

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Hydrodynamics in graphene: Linear-response transport

et al. 2015

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“…The carrier relaxation dynamics is determined within the second-order Born-Markov approximation resulting in a Boltzmann-like scattering equation [3,18,19,21]:…”

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confidence: 99%

Experimentally accessible signatures of Auger scattering in graphene

2016

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The gapless and linear electronic band structure of graphene opens up Auger scattering channels bridging the valence and the conduction band and changing the charge carrier density. Here, we reveal experimentally accessible signatures of Auger scattering in optically excited graphene. To be able to focus on signatures of Auger scattering, we apply a low excitation energy, weak pump fluences, and a cryostatic temperature, so that all relevant processes lie energetically below the optical phonon threshold. In this regime, carrier-phonon scattering is strongly suppressed and Coulomb processes govern the carrier dynamics. Depending on the excitation regime, we find an accumulation or depletion of the carrier occupation close to the Dirac point. This reflects well the behavior predicted from Auger-dominated carrier dynamics. Based on this observation, we propose a multicolor pump-probe experiment to uncover the extreme importance of Auger channels for the nonequilibrium dynamics in graphene.

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“…It turns out, however, that the system possesses another (nearly) conserved density which is the 'imbalance' mode corresponding to the total number of electrons and holes (as opposed to their difference related to the charge density) [240][241][242][243][244][245][246][247]. Away from the neutral (particle-hole symmetric) regime its relaxation takes place through the Auger-type processes with the still slower rate of order Г imb ~ T 4 /μ 3 .…”

Section: Holographic Transport: Dirac/weyl Materialsmentioning

confidence: 99%

Demystifying the holographic mystique: A critical review

Khveshchenko¹

2016

Lith. J. Phys.

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Thus far, in spite of many interesting developments, the overall progress towards a systematic study and classification of various 'strange' metallic states of matter has been rather limited. To that end, it was argued that a recent proliferation of the ideas of holographic correspondence originating from string theory might offer a possible way out of the stalemate. However, after almost a decade of intensive studies into the proposed extensions of the holographic conjecture to a variety of condensed matter problems, the validity of this intriguing approach remains largely unknown. This discussion aims at ascertaining its true status and elucidating the conditions under which some of its predictions may indeed be right (albeit, possibly, for a wrong reason).Keywords: strongly correlated systems, holographic correspondence, transport theory, strange metals, analogue gravity PACS: 71.27.+a Condensed matter holography: the promiseAmong the outstanding grand problems in condensed matter physics is that of a deeper understanding and classification of the so-called 'strange metals' or compressible non-Fermi liquid (NFL) states of the strongly interacting systems. However, despite all the effort and a plethora of the important and nontrivial results obtained with the use of the traditional techniques, this program still remains far from completion.As an alternate approach, over the past decade there have been numerous attempts inspired by the hypothetical idea of holographic correspondence which originated from string/gravity/high energy theory (where it is known under the acronym AdS/ CFT) to adapt its main concepts to various condensed matter (or, even more generally, quantum manybody) systems at finite densities and temperatures [1][2][3][4][5][6][7].In its original context, the bona fide holographic principle postulates that certain d + 1-dimensional ('boundary') quantum field theories (e. g. the maximally supersymmetric SU(N) gauge theory) may allow for a dual description in terms of a string theory which, upon a proper compactification, amounts to a certain d + 2-dimensional ('bulk') supergravity. Moreover, in the strong coupling limit (characterized in terms of the t'Hooft coupling constant λ = g 2 N >> 1) and for a large rank N > > 1 of the gauge symmetry group, the bulk description can be further reduced down to a weakly fluctuating gravity model which can even be treated semiclassically at the lowest (0th) order of the underlying 1/N-expansion.In the practical applications of the holographic conjecture, the partition function of a strongly interacting boundary theory with the Lagrangian L(ϕ a ) would then be approximated by a saddle-point (classical) value of the bulk action described by the Lagrangian L(g μν ,…) which includes gravity and other fields dual to their boundary counterparts [1][2][3][4][5][6][7][8] (1) evaluated with the use of a fixed background metric ,while any quantum corrections would usually be neglected by invoking the small parameter 1/N.

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Collision-dominated nonlinear hydrodynamics in graphene

Cited by 123 publications

References 58 publications

Hydrodynamics in graphene: Linear-response transport

Hydrodynamics in graphene: Linear-response transport

Experimentally accessible signatures of Auger scattering in graphene

Demystifying the holographic mystique: A critical review

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