Internodal excitonic state in a Weyl semimetal in a strong magnetic field
Abstract
The simplest Weyl semimetal with broken time-reversal symmetry consists of a pair of Weyl nodes located at wave vectors Kτ =τ b in momentum space with τ = 1 the node index and chirality. The electronic dispersion near each node is linear. In a magnetic field B along b, this dispersion is modified into a series of positive and negative energy Landau levels n= 1, 2,… ,which disperse along the direction of the magnetic field, and a chiral Landau level, n=0, with a linear dispersion given by eτ ,n=0( kz) =-τ vFkz, where kz is the component of the wave vector k along the magnetic field and vF is the Fermi velocity. In the extreme quantum limit, the Fermi level is in the chiral levels near the Dirac point. When Coulomb interaction is considered, a Weyl semimetal may be unstable towards the formation of a condensate of internodal electron-hole pairs. In this article we use the full long-range Coulomb interaction and the self-consistent Hartree-Fock approximation to generate the condensed state. We study its stability with respect to a change in the Fermi velocity, doping and strength of the Coulomb interaction and also consider Weyl nodes with higher Chern number C=2,3. We derive the response functions of the excitonic state in the generalized random-phase approximation (GRPA). We show that, in the mean-field gap induced by the internodal coherence, there is, in the GRPA excitonic response, a series of bound electron-hole states with a binding energy that decreases until the Hartree-Fock energy gap is reached. In addition, there is a collective mode gapped at exactly the plasmon frequency: the gapless mode present in the proper excitonic response function is pushed to the plasmon frequency by the long-range Coulomb interaction.
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