Litcius/Paper detail

Weyl–Wigner description of massless Dirac plasmas: ab initio quantum plasmonics for monolayer graphene

J. L. Figueiredo, João P. S. Bizarro, Hugo Terças

2022New Journal of Physics15 citationsDOIOpen Access PDF

Abstract

Abstract We derive, from first principles and using the Weyl–Wigner formalism, a fully quantum kinetic model describing the dynamics in phase space of Dirac electrons in single-layer graphene. In the limit ℏ → 0, we recover the well-known semiclassical Boltzmann equation, widely used in graphene plasmonics. The polarizability function is calculated and, as a benchmark, we retrieve the result based on the random-phase approximation. By keeping all orders in ℏ , we use the newly derived kinetic equation to construct a fluid model for macroscopic variables written in the pseudospin space. As we show, the novel ℏ -dependent terms can be written as corrections to the average current and pressure tensor. Upon linearization of the fluid equations, we obtain a quantum correction to the plasmon dispersion relation, of order ℏ 2 , akin to the Bohm term of quantum plasmas. In addition, the average variables provide a way to examine the value of the effective hydrodynamic mass of the carriers. For the latter, we find a relation in which Drude’s mass is multiplied by the square of a velocity-dependent, Lorentz-like factor, with the speed of light replaced by the Fermi velocity, a feature stemming from the quasi-relativistic nature of the Dirac fermions.

Topics & Concepts

PhysicsQuantum mechanicsSemiclassical physicsGrapheneDispersion relationWigner distribution functionDirac fermionRandom phase approximationPlasmonElectronDirac equationQuantum electrodynamicsQuantumGraphene research and applicationsQuantum Electrodynamics and Casimir EffectQuantum and electron transport phenomena